JP2020089828A - Iron frame automatic paint device and iron frame paint method - Google Patents

Abstract

To provide an iron frame automatic paint device which can achieve automation of paint work to an iron frame, to which a gusset plate etc. is attached, with easy work.SOLUTION: An iron frame automatic paint device 100 includes: paint spray nozzles 112 which spray a paint to a surface of an iron frame Y while moving; position display means 106 which indicates a position of a gusset plate etc. X attached to the iron frame Y; and position detection means 108 which detects the position of the gusset plate etc. X by using the position display means 106. At the position of the gusset plate etc. X detected by the position detection means 108, the spray of the paint from the paint spray nozzles 112 starts or stops.SELECTED DRAWING: Figure 1

Description

The present invention relates to a steel frame automatic coating device for coating the surface of a steel frame to which a gusset plate is attached, for example, and a steel frame coating method.

In recent years, various types of work have been automated by machines. The painting work is no exception to this, and various techniques have been proposed for the surface painting of a relatively long steel frame (for example, for construction).

For example, Patent Document 1 discloses a method of correcting a position error of a self-propelled carriage equipped with a painting robot that performs spray painting on a steel frame used for a high-rise building.

JP-A 61-239305

However, there has been a problem that automation of steel frame painting work has not progressed as much as automation of painting work for other objects. The reason is that the steel frame has a plurality of gusset plates and short steel frames (erection piece steel frames) used when joining other steel frames at the site (hereinafter, these are collectively referred to as "gusset plates, etc."). This is because it is often attached to the steel frame in advance by means of welding or the like before painting, and the gusset plate or the like becomes an obstacle when attempting to automate the painting work.

Of course, even if a gusset plate or the like is attached, it is possible to automatically perform the painting work by programming in advance. However, for example, the structure of the steel frame used in one building is becoming more and more complicated, and it is rare that there are multiple steel frames with the same number of gusset plates, etc., attached at exactly the same position. The number and position of the gusset plates, etc. attached to the are often different from each other. For this reason, there has been a problem that it takes too much time to individually perform programming according to the gusset plate or the like attached to each steel frame.

The present invention has been made to solve such a problem, and an object thereof is an automatic steel frame coating device that can realize automation of a coating work on a steel frame to which a gusset plate or the like is attached by a simple operation, and It is to provide a method for painting a steel frame.

According to one aspect of the invention,
A paint spray nozzle that sprays paint on the surface of the steel frame while moving,
Position display means for indicating the position of the gusset plate or the like attached to the steel frame,
And a position detection unit for detecting the position of the gusset plate or the like using the position display unit,
At the position of the gusset plate or the like detected by the position detecting means, there is provided an automatic steel frame coating device for starting or stopping the spraying of the paint from the paint spraying nozzle.

Suitably, the paint injection nozzle is reciprocating with respect to the steel frame to inject the paint,
The position display means has a pair of markers that display the front and rear positions of at least one of the gusset plates and the like attached to the steel frame.

Suitably, it further comprises a paint injection nozzle moving means for moving the paint injection nozzle to a retracted position where it does not hit the gusset plate or the like at the position of the gusset plate or the like.

Suitably, the position display means, in the outward path to the steel frame of the paint injection nozzle, an on-marker for starting the injection of the paint from the paint injection nozzle, and of the paint from the paint injection nozzle in the outward path. And an off marker for stopping the injection.

Preferably, a magnetic sensor is used as the position detecting means.

Preferably, a laser is used as the position detecting means.

Preferably, the paint injection nozzles are arranged on both side surfaces of the steel frame, respectively.

According to another aspect of the present invention,
Detecting the position of each gusset plate or the like by the position detecting means using the position display means for indicating the position of each gusset plate or the like attached to the steel frame,
A steel frame coating method is provided in which the spraying of the paint from the paint spraying nozzle is started or stopped at the position of each gusset plate or the like detected by the position detection means.

According to the present invention, by using the position display means and the position detection means, it is possible to realize automation of the coating work on the steel frame to which the gusset plate or the like is attached by a simple work, and an automatic steel frame coating device, and It was possible to provide a steel frame painting method.

It is a front view which shows the whole steel frame automatic coating device 100 which concerns on 1st Embodiment. It is a top view which shows the whole steel frame automatic coating device 100 which concerns on 1st Embodiment. It is a right side view which shows the whole steel frame automatic coating device 100 which concerns on 1st Embodiment. It is a flowchart until the painting on the steel frame Y is started. It is a front view which shows the whole steel frame automatic coating device 100 which concerns on 2nd Embodiment. It is a top view which shows the whole steel frame automatic coating device 100 which concerns on 2nd Embodiment. It is a right view which shows the whole steel frame automatic coating device 100 which concerns on 2nd Embodiment. It is a top view for explaining distance measurement in steel frame automatic coating device 100 concerning a 2nd embodiment. It is a front view for explaining the case where the chain 160 and the sprocket 162 are used as a moving means of the coating unit main body 110. It is a figure which shows an example of the shape of X, such as a gusset plate.

<First Embodiment>
<Structure of automatic steel frame coating device 100>
Hereinafter, a first embodiment according to the present invention will be described with reference to the drawings. The overall configuration of the steel frame automatic coating device 100 according to the present embodiment will be described with reference to FIGS. 1 to 3. The automatic steel frame coating apparatus 100 generally includes a coating unit 102, a steel frame mounting table 104, a position display means 106, and a position detection means 108.

The coating unit 102 is for spraying paint onto the steel frame Y to which the gusset plate X is attached by means such as welding, and generally, the paint unit main body 110, the paint spray nozzle 112, the side surface coating slider 114, and the side surface. It is provided with a slider for vertically moving coating 115, a top surface paint spraying nozzle 116, a top surface coating slider 118, wheels 120, a traveling motor 122, a paint tank 124, a compressor 126, and a control device 128. There is.

The coating unit main body 110 collectively moves the respective members constituting the coating unit 102, and in the present embodiment, has a frame structure in which a plurality of shaped steels are combined. Of course, the coating unit body 110 is not limited to the frame structure.

The paint spray nozzle 112 is a member that sprays a desired paint onto a side surface (for example, a web portion of an H-shaped steel) of the steel frame Y while moving together with the coating unit body 110. In this embodiment, the paint spray nozzle 112 faces each other. A pair of paint injection nozzles 112 are prepared. Thereby, for example, both sides of the web portion of H-section steel can be coated at once. Of course, the number of paint injection nozzles 112 is not limited to two, and may be one to paint only one side surface from which, or three or more.

The side surface coating slider 114 is a device that reciprocates the above-described paint injection nozzle 112 in the horizontal direction in which the paint injection nozzle 112 approaches and separates from the steel frame Y, and one side surface coating slider 114 is used for one paint injection nozzle 112. .. That is, in the present embodiment, the pair of side surface coating sliders 114 is used and attached to both side portions of the coating unit body 110. As an example of the side surface coating slider 114, one using a ball screw, a cylinder type using hydraulic pressure or pneumatic pressure, and the like can be considered.

The side surface painting vertical movement slider 115 is a device that reciprocates the paint injection nozzle 112 in the vertical vertical direction together with the side surface coating slider 114 described above, and one side surface painting vertical movement slider with respect to one paint injection nozzle 112. 115 is used. That is, in the present embodiment, the pair of side surface painting vertical movement sliders 115 are used and are attached to both side portions of the coating unit body 110, respectively. As an example of the side surface painting vertical movement slider 115, similar to the side surface coating slider 114 described above, one using a ball screw, a cylinder type using hydraulic pressure or pneumatic pressure, and the like can be considered.

In the case of the present embodiment, the side surface coating slider 114 and the side surface coating vertical movement slider 115 described above constitute a paint injection nozzle moving means.

The top surface paint spray nozzle 116 is a member that sprays a desired paint onto the top surface of the steel frame Y (for example, the outer surface of the flange of the H-shaped steel). In the present embodiment, one top surface paint spray nozzle 116 that sprays paint from the upper side to the lower side of the H-section steel to be painted is prepared. Of course, the number of top surface paint injection nozzles 116 may be two or more. Further, if the top surface of the steel frame Y does not need to be painted, it is not necessary to provide the top surface paint spray nozzle 116.

The top surface painting slider 118 is a device that reciprocates the above-mentioned top surface paint spray nozzle 116 in the horizontal direction that is a direction orthogonal to the paint spray direction, and is attached to the upper side of the coating unit body 110. As an example of the top surface coating slider 118, a ball screw type one, a cylinder type one using hydraulic pressure or pneumatic pressure, and the like can be considered like the side surface coating slider 114.

The wheel 120 is adapted to reciprocate the coating unit main body 110 in the horizontal direction, and is attached to the lower end of the coating unit main body 110.

The traveling motor 122 is a member for supplying a predetermined driving force to the wheels 120.

The paint tank 124 is a member for storing the paint sprayed from the paint spray nozzle 112 or the ceiling paint spray nozzle 116 toward the steel frame Y, and is attached to a predetermined position in the coating unit body 110. The number of paint tanks 124 may be one, or a plurality of paint tanks 124 may be provided if necessary when spraying paints of different types and colors from the nozzles 112 and 116.

The compressor 126 is a device that generates compressed air that is jetted together with the paint when jetting a predetermined paint from each of the nozzles 112 and 116. This compressor 126 is also attached at a predetermined position in the coating unit body 110, and the number of compressors 126 is not particularly limited.

The control device 128 is a device for controlling the operation of each member attached to the coating unit 102. The method of coating the steel frame Y by the control device 128 will be described later. Although not shown, the control device 128 includes input means such as a keyboard and a mouse used to input necessary data in advance and store the data in the control device 128, a display monitor and the like. A PLC (Programmable Logic Controller) can be cited as an example of the control device 128.

The steel frame mounting table 104 is a table on which the steel frame Y to be coated by using the automatic steel frame coating apparatus 100 is mounted. The steel frame mounting table 104 of the present embodiment supports the steel frame Y substantially horizontally from the floor surface at a predetermined height and is arranged at a position where it can pass through the inside of the coating unit body 110 of the coating unit 102. ..

The position display means 106 indicates the position of each gusset plate or the like X attached to the steel frame Y, and roughly includes a magnet mounting lane 130 and a magnetic marker 132 as a marker for displaying the front and rear positions of the gusset plate or the like X. Is equipped with.

The magnet attachment lanes 130 are continuous long plate-shaped members to which the magnet markers 132 are attached by the user. In the case of the present embodiment, a pair of magnet attachment lanes 130 is provided on both side surfaces of the steel mounting table 104. Are arranged side by side in two rows. That is, in this embodiment, four magnet mounting lanes 130 are used. Further, the “continuous long plate-shaped member” used as the magnet mounting lane 130 may be, for example, a “C-shaped channel”. As described above, by using the “continuous long plate-shaped member”, there is an advantage that the magnet marker 132 can be attached at any position.

The magnet marker 132 is a marker formed of a member having a magnetic force, and a plurality of magnet markers 132 are attached and used at predetermined positions in each of the four magnet attachment lanes 130.

Specifically, the upper side of the pair of magnet mounting lanes 130 arranged in the upper and lower sides is treated as the "on magnet mounting lane 134", and the lower side is treated as the "off magnet mounting lane 136". After mounting the steel frame Y on the steel frame mounting table 104, a magnet marker (at a position on the on-magnet attachment lane 134 corresponding to a position where the coating unit 102 starts coating (hereinafter, referred to as “coating start position S”)). On marker) 132 is attached. In general, bolt holes are often provided at the end of the steel frame Y, so it is preferable to set the coating start position S at a position avoiding the bolt holes. Of course, the coating start position S may be set at the end of the steel frame Y. Further, the coating start position S may be set to a so-called "friction surface boundary position".

After that, from the end to which the coating start position S of the steel frame Y belongs to the end on the opposite side, to the position on the off-magnet mounting lane 136 corresponding to the front position where the first gusset plate etc. X exists, Another magnetic marker (off marker) 132 is attached.

Further proceeding, another magnet marker (on marker) 132 is attached to the position on the on magnet attachment lane 134 corresponding to the position after passing the first gusset plate or the like X.

In this way, one gusset plate or the like X has the magnet marker (off marker) 132 attached to the corresponding position on the off magnet attachment lane 136 on the front side (painting start position S) side and the opposite side. It is in a state of being sandwiched by another magnet marker (on marker) 132 attached at a corresponding position on the on-magnet attachment lane 134 in FIG.

After that, the same work is performed every time the gusset plate or the like X is present, and finally, on the off-magnet attachment lane 136 corresponding to the position where the painting by the painting unit 102 is finished (hereinafter, referred to as “painting finish position E”). The magnetic marker (off marker) 132 is attached to the position. It should be noted that, like the coating start position S described above, the coating end position E is also preferably set at a position avoiding the bolt holes formed at the end of the steel frame Y, but of course the coating end position E is set to the steel frame Y. It may be set at the end of Y. Further, the coating end position E may be set to a so-called "friction surface boundary position".

The position detection unit 108 detects the position of each gusset plate or the like X using the position display unit 106 described above, and in the present embodiment, the magnetic sensor 140 that can detect the magnet marker 132 is used. Further, the position detecting means 108 is attached to the coating unit main body 110 so as to be at the same position as the coating material injection nozzle 112 in the traveling direction of the coating unit 102.

Further, at least two sets of the position detecting means 108 in the present embodiment are provided so that the magnet markers 132 attached to the magnet attaching lanes 130 arranged on both side surfaces of the steel frame mounting table 104 can be read. Further, each position detecting means 108 has at least two magnetic sensors 140 at the top and bottom so that the magnetic marker 132 attached to the on-magnet attachment lane 134 and the magnetic marker 132 attached to the off-magnet attachment lane 136 can be read. Is equipped with.

Further, each position detecting means 108 can transmit a signal indicating which magnetic sensor 140 has detected to the control device 128 of the coating unit 102 when any of the magnetic sensors 140 detects the magnetic marker 132. There is.

<Painting method of steel frame Y by the steel frame automatic painting device 100 according to the first embodiment>
Next, a method of coating the surface of the steel frame Y using the above-described steel frame automatic coating device 100 will be described with reference to FIG. First, the steel frame Y to be coated is mounted on the steel frame mounting table 104, and necessary fixing and cleaning operations (adjustment of the coating base) and curing (masking) are performed (step S1). Needless to say, the steel frame Y may be mounted and fixed on the steel frame mounting table 104 after the skeleton work and the curing are performed first.

After that, the basic information necessary for painting is input to the control device 128 using the input means (step S2). Here, the "basic information" includes, for example, the height and width of the steel frame Y to be coated, the moving speeds of the paint spray nozzle 112 and the top paint spray nozzle 116 by the sliders, the paint spray nozzle 112 and the top paint spray. The distance from the tip of the nozzle 116 to the surface of the steel frame Y, the amount of paint sprayed from the paint spray nozzle 112 and the top paint spray nozzle 116, the moving speed of the coating unit body 110, the side coating slider 114 and the top coating slider. The moving speed of the paint spraying nozzle 112 and the top surface paint spraying nozzle 116 by 118, and the vertical moving distance of the paint spraying nozzle 112 are considered. Of course, the "basic information" is not limited to these.

After that, as described above, a plurality of magnet markers (on marker and off marker) 132 are attached at predetermined positions in the magnet attachment lane 130 of the position display means 106 (step S3). Of course, this work is performed on both the left and right sides of the steel frame Y. This is because, depending on the type of the gusset plate or the like X, it may be provided on only one of the left and right sides of the steel frame Y, so that the attachment positions of the plurality of magnet markers 132 may not be symmetrical.

After the above preparation is completed, a start button (not shown) of the steel frame automatic coating device 100 is pressed to start the coating work (step S4).

When the coating work is started, the control device 128 rotates the traveling motor 122 to rotate the wheels 120, and the coating unit 102 starts to move toward the steel frame Y. The coating unit 102 moves, and the position detecting means 108 is attached to the first magnet marker (on marker) 132 (on the leftmost end, “painting start position S” in FIG. 1) attached to the on-magnet attachment lane 134. The magnetic marker 132) is transmitted to the control device 128.

The control device 128, which has received the signal indicating that the magnet marker (on marker) 132 at the coating start position S is detected from the position detection means 108, operates the compressor 126 to paint the paint from the paint tank 124 together with the compressed air. Spraying is performed from the spraying nozzle 112 and the top surface paint spraying nozzle 116 toward the surfaces of the steel frames Y facing each other.

Further, the control device 128 continues to move the coating unit 102 while spraying the paint. At this time, the top surface coating slider 118 does not move the position of the top surface paint spraying nozzle 116, and the top surface is coated in a straight line with respect to the longitudinal direction of the steel frame Y.

After that, when the position detecting unit 108 detects the magnet marker (off marker) 132 attached to the off magnet attachment lane 136 on the front side of the first gusset plate or the like X, the control device 128 stops the traveling motor 122. The movement of the coating unit 102 is stopped, and the supply of compressed air to the paint injection nozzle 112 (and the top surface paint injection nozzle 116) is stopped to stop the paint injection. Further, the distance A that the coating unit 102 has moved from the coating start position S to the position where the magnet marker (off marker) 132 attached to the off magnet attachment lane 136 is detected is calculated from, for example, the number of rotations of the wheel 120. Then, it is stored in the control device 128. Of course, the measuring method of the distance A is not limited to this, and for example, the moving distance of the coating unit main body 110 itself may be measured.

After that, the control device 128 operates the side surface coating slider 114 to move the paint injection nozzle 112 in the direction away from the steel frame Y, and separates the tip of the paint injection nozzle 112 to a position where it does not interfere with the gusset plate X or the like. By the way, the movement of the paint injection nozzle 112 is stopped.

When the movement of the paint spray nozzle 112 to the retracted position by the side coating slider 114 is completed, the control device 128 operates the traveling motor 122 again to start the movement of the coating unit 102. At the same time, the spraying of the paint from the top surface paint spraying nozzle 116 is restarted.

After that, the control device 128, which has received a signal from the position detection means 108 indicating that the magnet marker (on marker) 132 in the on magnet attachment lane 134 has been detected, the paint from the traveling motor 122 and the top paint injection nozzle 116. Is stopped, and the side coating slider 114 is operated to move the paint injection nozzle 112 in the direction toward the steel frame Y. Further, from the position where the magnet marker (off marker) 132 attached to the off magnet attachment lane 136 is detected immediately before to the position where the magnet marker (on marker) 132 attached to the next on magnet attachment lane 134 is detected. Similarly, the distance B is calculated from the number of rotations of the wheel 120 and stored in the control device 128.

After moving the paint injection nozzle 112 to a predetermined position near the surface of the steel frame Y, the control device 128 starts the supply of compressed air and restarts the injection of the paint from the paint injection nozzle 112. Further, the control device 128 operates the traveling motor 122 to restart the movement of the coating unit 102 and the injection of the paint from the top surface paint injection nozzle 116.

After restarting the movement of the coating unit 102, when the position detecting means 108 transmits to the control device 128 that the next magnet marker (off marker) 132 attached to the off magnet attachment lane 136 is detected, the control device 128 will Similarly, the traveling motor 122 is stopped, the paint injection is stopped, the distance C to the same position is calculated, and the paint injection nozzle 112 is separated from the steel frame Y.

In this way, the coating unit 102 is moved while repeating the spraying of the coating material on and off, and the off-magnet mounting lane at the “coating end position E” at the distance preset from the coating start position S is set. When the position detection means 108 detects the magnet marker (off marker) 132 attached to the 136, the control device 128 stops the traveling motor 122 to stop the spraying of the paint, and at the same time, the side surface painting vertical movement slider 115. Is operated to move the paint injection nozzle 112 in the vertical direction (for example, the downward direction in FIG. 1) by a preset distance.

After that, the control device 128 rotates the traveling motor 122 in the opposite direction to the previous direction, and moves the coating unit 102 toward the "coating start position S".

Here, the positions of the respective magnetic markers (on marker and off marker) 132 attached to the on-magnet attachment lane 134 and the off-magnet attachment lane 136 when moving from the painting start position S to the painting end position E first, and Since the distance between the magnetic markers (on marker and off marker) 132 is recorded in the control device 128, when returning toward the coating start position S, each magnetic marker (on marker and off marker) 132 is recorded. Is detected by the position detection means 108, the presence/absence of paint injection and the distance of the paint injection nozzle 112 to the steel frame Y are controlled based on the recording in the control device 128. Of course, when returning from the coating end position E to the coating start position S, the position of the magnet marker (on marker) 132 attached to the on magnet attachment lane 134 is, on the contrary, to turn off the spray of the paint. It should be read as position. Similarly, the position of the magnet marker (off marker) 132 attached to the off magnet attachment lane 136 is conversely read as the position at which the paint injection is turned “on”.

Further, with respect to the top surface of the steel frame Y, the top surface coating slider 118 horizontally moves the top surface paint spraying nozzle 116 in a direction orthogonal to the longitudinal direction of the steel frame Y, so that the coating start position S to the coating end position E first. It will be painted in a straight line in the same way next to the straight paint position where it was painted when it was moved to.

When the coating unit 102 returns to the coating start position S, the controller 128 operates the side coating vertical movement slider 115 to move the coating material injection nozzle 112 vertically (vertically downward in FIG. 1) by a preset distance. ), the coating unit 102 is moved to the coating end position E while coating the steel frame Y again. At that time, without detecting each magnet marker (on marker and off marker) 132 by the position detecting means 108, based on the record in the control device 128, the presence or absence of the injection of the paint and the steel frame Y of the paint injection nozzle 112. Control the distance to. Similarly, the top surface paint injection nozzle 116 is horizontally moved by the top surface coating slider 118.

In this way, the coating unit 102 is moved back and forth a required number of times to coat the steel frame Y up to the lower end in the vertical direction. The entire top surface of the steel frame Y is also painted. Finally, after removing the masking or the like and manually painting the necessary portions, the steel frame Y is lowered from the steel frame mounting table 104, whereby the painting work on the steel frame Y is completed. Of course, after lowering the steel frame Y from the steel frame mounting table 104, masking or the like may be removed from the steel frame Y or necessary portions may be manually painted.

<Characteristics of the steel frame automatic coating device 100 according to the first embodiment>
As described above, according to the automatic steel frame coating apparatus 100 of the above-described embodiment, the magnetic markers (on marker and off marker) 132 are attached at necessary positions according to the actual steel frame Y mounted on the steel frame mounting table 104. It is not necessary to take in complicated machining data from the CAD of the steel frame Y by simply performing such a simple work, and there is no need for complicated control programs or knowledge to assemble the control programs. It is possible to realize the automation of the painting work on the steel frame Y to which the X etc. are attached.

Further, by performing the coating while detecting the position of the gusset plate or the like X attached to the steel frame Y in the first outward path, the position detecting means 108 is only for detecting the position of the gusset plate or the like X without performing the coating. It is possible to reduce the total time required for painting the steel frame Y as compared with the case of moving.

<Modification>
In the above-described first embodiment, the position display means 106 and the position detection means 108 are provided on both side surfaces of the steel frame Y, but, for example, the gusset plate or the like X is attached at the same position on both side surfaces. In such a case, the position display means 106 and the position detection means 108 may be provided on only one of the side surfaces, and both paint injection nozzles 112 may be moved in the same manner to apply the coating on both side surfaces.

Further, although the magnetic marker 132 is used as the on-marker and the off-marker in the above-described first embodiment, the on-marker and the off-marker are not limited to this. Anything that can be detected by the approaching position detecting means 108 may be used.

<Second Embodiment>
Next, a second embodiment according to the present invention will be described with reference to FIGS. In the following description, the same parts as those in the first embodiment described above are designated by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

In the first embodiment, as the position display means 106 showing the position of each gusset plate or the like X attached to the steel frame Y, the on-marker and the off-marker attached at the necessary positions according to the actual article of the steel frame Y are detected. Although 108 is read in order, in the second embodiment, for example, a laser range finder 150 is used as the position detecting means 108, and a laser target 152 is used as the position displaying means 106. ..

Therefore, in the steel frame automatic coating device 100 according to the second embodiment, the magnet mounting lane 130 and the magnetic sensor 140 are not provided.

<Method of coating steel frame Y by automatic steel frame coating apparatus 100 according to the second embodiment>
When the steel frame Y is coated using the steel frame automatic coating device 100 according to the second embodiment, in addition to the case of the first embodiment, when the "basic information" is input in step S2, the above-described case is performed. The distance between the Xs such as the gusset plate is measured in advance using the position display means 106 and the position detection means 108.

Specifically, as shown in FIG. 8, for example, the laser range finder 150 attached to the coating unit main body 110 is disposed at the origin G, and the laser range finder 150 is attached to the origin G to serve as the position display unit 106. Of the laser target 152 of, for example, the coating start position S, the coating end position E, and the coating start position S side end and the coating end position E side end of each gusset plate or the like X, and the distance to each position is controlled by a controller. It will be stored in 128.

In this way, the control device 128 controls the traveling of the coating unit 102, the spraying of the paint from the paint spraying nozzle 112, etc. on the basis of the respective distances stored in the control device 128 as "basic information", Continue to paint the steel frame Y.

<Characteristics of the steel frame automatic coating device 100 according to the second embodiment>
As described above, according to the steel frame automatic coating device 100 according to the second embodiment, as in the case of the first embodiment, it is necessary from the origin G to match the actual structure of the steel frame Y mounted on the steel frame mounting table 104. By simply performing a simple operation such as measuring the distance to a certain position in advance using the laser range finder 150 and the laser target 152, there is no need to take in complicated processing data from the CAD of the steel frame Y, and It is possible to realize automation of the painting work on the steel frame Y to which a plurality of gusset plates X and the like are attached, without requiring a complicated control program or the like.

<Variation 1 throughout>
In the two embodiments described above, the control device 128 rotates the wheel 120 by rotating the traveling motor 122 to move the coating unit body 110, but the means for moving the coating unit body 110 is It is not limited to this. For example, as shown in FIG. 9, a chain 160 having a length sufficient to cover the movement range of the coating unit body 110 is stretched, and a sprocket 162 that meshes with the chain 160 is connected to the traveling motor 122. As a result, when the control device 128 rotates the traveling motor 122, the sprocket 162 rotates and the chain 160 is pulled in, whereby the coating unit main body 110 can be moved.

<Modification 2 throughout>
Further, similarly to the case where the moving distance of the coating unit body 110 is measured by the number of rotations of the wheels 120, the moving distance can be measured by using the number of rotations of the traveling motor 122. Of course, when using the sprocket 162, the number of rotations of the sprocket 162 may be used.

<Modification 3 throughout>
Further, in the two embodiments described above, the position detecting means 108 detects the coating start position S side end and the coating end position E side end of one gusset plate or the like X. By preliminarily storing the thickness of the coating unit main body 110 in the moving direction as “basic information” in the control device 128, for example, each distance can be grasped without detecting the end of the coating end position E side.

<Variation 4 throughout>
Further, for example, when the coating unit main body 110 reciprocates to sequentially paint from the upper side to the lower side of the steel frame Y in the vertical direction, the shape of the gusset plate or the like X is as shown in FIG. If the shape is such that it exists only on the upper side in the vertical direction, the paint injection nozzle 112 needs to be separated from the steel frame Y at the position of the gusset plate or the like X for the first few reciprocations, but Since the gusset plate or the like X does not exist at the position, it is not necessary to separate the paint injection nozzle 112.

Even in such a case, the position of the gusset plate or the like X is stored in the control device 128 in advance as "basic information", so that the vertical position of the paint injection nozzle 112 does not interfere with the gusset plate or the like X. Alternatively, the paint may be continuously jetted by the paint jetting nozzle 112 as if the gusset plate X or the like does not exist.

Further, if the projecting dimension of the gusset plate X or the like from the web portion surface of the steel frame Y is short and it is not necessary to separate the paint injection nozzle 112 from the steel frame Y, it is assumed that the gusset plate or the like X having the short projecting dimension does not exist. You may proceed with the painting work.

<Variation 5 throughout>
In the above, the case where the gusset plate X or the like does not exist on the top surface of the steel frame Y or the existence of the gusset plate X does not have to avoid the interference with the top surface paint spraying nozzle 116 will be described. It was However, when a gusset plate or the like X that needs to avoid interference with the top surface paint spraying nozzle 116 is also attached to the top surface of the steel frame Y, the paint used for the side surface coating described so far. The position display means 106 and the position detection means 108 used for the spray nozzle 112 may be further applied to the top surface paint spray nozzle 116. In that case, add a slider (not shown) for moving the top surface up and down for moving the tip of the top surface spraying nozzle 116 in a direction (vertical direction in the drawing) to move closer to and away from the top surface of the steel frame Y. become. Furthermore, the position display means 106 and the position detection means 108 may not be used for painting the side surface (for example, the web portion) of the steel frame Y, but may be used only for painting the top surface.

For example, when the magnet marker 132 is used as the position display unit 106 as in the “first embodiment”, two magnet mounting lanes 130 are used for the top surface.

The embodiments disclosed this time are to be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description but by the claims, and is intended to include meanings equivalent to the claims and all modifications within the scope.

DESCRIPTION OF SYMBOLS 100... Automatic steel frame coating device, 102... Coating unit, 104... Steel frame mounting table, 106... Position display means, 108... Position detection means 110... Coating unit main body, 112... Paint injection nozzle, 114... Side coating slider, 115... Side coating vertical movement slider, 116... Top surface paint spray nozzle, 118... Top surface coating slider, 120... Wheels, 122... Traveling motor, 124... Paint tank, 126... Compressor, 128... Control device 130... Magnet mounting Lane, 132... Magnetic marker, 134... On-magnet mounting lane, 136... Off-magnet mounting lane 140... Magnetic sensor 150... Laser distance meter, 152... Laser target 160... Chain, 162... Sprocket S... Painting start position, E... Painting End position, G... Origin X... Gusset plate, etc. Y... Steel frame

Claims (8)

A paint spray nozzle that sprays paint on the surface of the steel frame while moving,
Position display means for indicating the position of each gusset plate or the like attached to the steel frame,
And a position detection unit that detects the position of each of the gusset plates using the position display unit,
An automatic steel frame coating device for starting or stopping the injection of the paint from the paint injection nozzle at the position of each gusset plate or the like detected by the position detection means. The paint spray nozzle reciprocates with respect to the steel frame to spray the paint,
The automatic steel frame coating device according to claim 1, wherein the position display means includes a pair of markers that display the front and rear positions of at least one of the gusset plates and the like attached to the steel frame. The automatic steel frame coating device according to claim 1 or 2, further comprising a paint spray nozzle moving unit that moves the paint spray nozzle to a retracted position where it does not hit the gusset plate or the like at a position of the gusset plate or the like. The position display means, on the outward path of the paint injection nozzle with respect to the steel frame, an on-marker that starts the injection of the paint from the paint injection nozzle, and stops the injection of the paint from the paint injection nozzle on the outward path. The steel frame automatic coating device according to any one of claims 1 to 3, further comprising an off-marker. The automatic steel frame coating device according to any one of claims 1 to 4, wherein a magnetic sensor is used as the position detecting means. The steel frame automatic coating device according to claim 1, wherein a laser is used as the position detecting means. The steel frame automatic coating device according to any one of claims 1 to 6, wherein the paint injection nozzles are respectively arranged on both side surfaces of the steel frame. Detecting the position of each gusset plate or the like by the position detecting means using the position display means for indicating the position of each gusset plate or the like attached to the steel frame,
A method for coating a steel frame, which starts or stops the injection of paint from a paint injection nozzle at the position of each of the gusset plates and the like detected by the position detection means.

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