The present invention relates to an after-treatment method and facility for coarse aluminum castings. More particularly, it relates to a method and facility wherein a robot having a holding means that can hold two coarse aluminum castings carries the coarse aluminum castings one by one to a first and a second machining unit that carry out the after-treatment of them, at the time they are carried out by a cellular manufacturing system.
One of the existing methods that continuously carries out after-treatments of coarse aluminum castings that have been taken out of a casting machine is one in which a first and a second machining unit are placed side by side, and one robot carries one by one the coarse aluminum castings to the first and the second machining unit and takes them out one by one.
However, according to the existing method of after-treatment for coarse aluminum castings as constructed above, the robot cannot efficiently hold and carry them to the first and the second machining unit.
The problem to be resolved is that the one robot cannot efficiently hold and pass coarse aluminum castings to two units, i.e., a first and a second machining unit.
In order to resolve this problem, the method of carrying out the after-treatment for coarse aluminum castings of the present invention is one in which a robot having a holding means that can hold two coarse aluminum castings carries each one one by one to the first and the second machining unit that carry out the after-treatment for them, during the period that the after-treatment is continuously carried out by a cellular manufacturing system. It comprises holding an untreated coarse aluminum casting that is located at a predetermined carrying-in corner with the holding means and by the robot carrying it to the first machining unit, at the first machining unit holding a treated coarse aluminum casting that has been treated by the first machining unit with the holding means as well as transferring the untreated coarse aluminum casting from the holding means to the first machining unit, by the robot carrying the treated coarse aluminum casting that has been treated by the first machining unit to the second machining unit, at the second machining unit holding a treated coarse aluminum casting that has been treated by the second machining unit with the holding means as well as transferring the treated coarse aluminum casting that has been treated by the first machining unit from the holding means to the second machining unit, and by the robot carrying the treated coarse aluminum casting that has been treated by the second machining unit to a predetermined carrying-out corner.
In the present invention, the term “after-treatment” means carrying out at least one of the processes of cutting, trimming, and drilling at least one of a portion near a sprue, an overflowing portion, flashes, and a surface (surface processing) of a coarse aluminum casting.
Further, the term “machining unit” means a unit that carries out at least one of the processes of cutting, trimming, and drilling at least one of a portion near a sprue, an overflowing portion, flashes, and a surface (surface processing) of a coarse aluminum casting. The main parts of the machining unit are an overflow-breaking unit that breaks or cuts an overflowing portion of a coarse aluminum casting, a sprue-gate cutting unit that cuts the portion near a sprue-gate of a coarse aluminum casting, a surface-finishing unit that carries out a surface-finishing of a coarse aluminum casting, a flash-eliminating unit that eliminates flashes of a coarse aluminum casting, a surface-processing unit that carries out the surface-processing of a coarse aluminum casting, etc.
The term “surface processing of a coarse aluminum casting” means the process that must be done before carrying out some post-processes such as various tests to be done after the after-treatment so as to produce an aluminum casting having no defect.
As discussed above, the present invention is a method of carrying out the after-treatment for coarse aluminum castings that are continuously carried out by a cellular manufacturing system (a manufacturing system carried out at stalls), wherein a robot having a holding means that can hold two coarse aluminum castings carries, one by one, each of the coarse aluminum castings to the first and the second machining unit that carry out the after-treatment for them. The method comprises holding an untreated coarse aluminum casting that is located at a predetermined carrying-in corner with the holding means and by the robot carrying it to the first machining unit, at the first machining unit holding a treated coarse aluminum casting that has been treated by the first machining unit with the holding means as well as transferring the untreated coarse aluminum casting from the holding means to the first machining unit, carrying the treated coarse aluminum casting that has been treated by the first machining unit to the second machining unit by the robot, at the second machining unit holding a treated coarse aluminum casting that has been treated by the second machining unit with the holding means as well as transferring the treated coarse aluminum casting that has been treated by the first machining unit from the holding means to the second machining unit, and by the robot carrying the treated coarse aluminum casting that has been treated by the second machining unit to a predetermined carrying-out corner.
Accordingly, the robot can carry the coarse aluminum casting of which the after-treatment has already been done by the first machining unit to the second machining unit while the first machining unit is carrying out the after-treatment of an untreated coarse aluminum casting. The robot can also carry an untreated coarse aluminum casting to the first machining unit while the second machining unit is carrying out the after-treatment of the treated coarse aluminum casting that has been treated by the first machining unit. Therefore, the invention can achieve an excellent effect in that it can more efficiently operate a machining unit than can a conventional method of this kind of after-treatment.
Now we discuss the details of the after-treatment facility of the best mode of the present invention, based on
The robot 3 (FANUCS-430iF, made by FANUC Ltd.) has multiple joints with six axes. The control for turning an arm 5 of the robot 3 is performed by the program that is stored in the controller (not shown), wherein the program is made by “teaching” in advance. A holding mechanism 6 for a coarse aluminum casting (W) is mounted on the arm 5 of the robot 3 so as to hold two of the coarse aluminum castings. As shown in
Based on
Then, after getting the pair of claw-parts 9, 9 to hold the treated work that has been treated by the machining unit I and that has been located on the setting table (i), the holding means 6 moves and removes the treated work that has been treated by the machining unit I from the setting table (i) as well as bringing the untreated work to the setting table (i), as shown in
By rotating the treated work by 180 degrees with the holding means 6, the portion of the treated work on which the after-treatment is to be carried out is changed.
Next, as shown in
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2004-197098 | Jul 2004 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2005/011972 | 6/29/2005 | WO | 00 | 12/29/2006 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/003947 | 1/12/2006 | WO | A |
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Number | Date | Country | |
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20090193954 A1 | Aug 2009 | US |