This application is a National Stage of International Application No. PCT/JP2007/071060, filed Oct. 29, 2007, claiming priority based on Japanese Patent Application No. 2006-293171, filed Oct. 27, 2006, the contents of all of which are incorporated herein by reference in their entirety.
The present invention relates to a die used for the extrusion molding of a honeycomb structure, and its production method.
A ceramic honeycomb structure (simply called “honeycomb structure” below) used as a filter for cleaning an exhaust gas, etc. is produced by extruding a moldable ceramic material through a honeycomb-structure-molding die (simply called “molding die” or “die”) to form a honeycomb molding, and drying and sintering it. As shown in
As shown in
The molding die 10 is produced by forming apertures 40 by drilling, etc. in the die-forming work 21 having a projecting groove-having surface 31 as shown in
In a conventional extrusion-molding die, a groove-having surface 31 having an outer periphery 32, which is square as it is formed when viewed from above as shown in
However, when the outer periphery 32 of the groove-having surface 31 has a square shape as shown in
Using a die-forming work 21 having a groove-having surface 31 having a circularly formed outer periphery 32 to form grooves 30 by machining, the above inefficiency of machining some grooves 30 that are not used for extrusion can be avoided. However, in the machining of the groove-having surface 31 having a circular outer periphery 32 to form grooves 30, some grooves 30 are at extremely small angles 70 to the outer periphery 32 of the groove-having surface 31 as shown in
Accordingly, an object of the present invention is to provide a die for extrusion-molding a honeycomb structure, which has a structure needing the formation of some grooves not used for extrusion molding as little as possible, and less damaging a rotating tool when forming the grooves, and a method for producing a die with reduced number of groove-machining steps.
As a result of intensive research in view of the above object, the inventors have found that with an angle of 30° or more between the outer periphery of the groove-having surface and the progression direction of a rotating tool, breakage, etc. can be effectively avoided in the rotating tool when forming grooves. The present invention has been completed based on such finding.
Thus, the die of the present invention for molding a material to a honeycomb structure has large numbers of grooves, a surface having the grooves having an outer periphery in a polygonal shape having 6 or more corners, and the grooves being crossing the outer periphery at an angle of 30° or more.
The method of the present invention for producing a die having large numbers of grooves for molding a material to a honeycomb structure comprises machining a die-forming work to form a groove-having surface having an outer periphery in a polygonal shape having 6 or more corners, such that the outer periphery crosses the grooves at an angle of 30° or more, and then forming the grooves.
a) is a schematic cross-sectional view showing one example of the honeycomb structures perpendicularly to flow paths.
b) is a schematic cross-sectional view showing one example of the honeycomb structures in parallel to flow paths.
a) is a perspective view showing a conventional molding die on the groove-having surface side.
b) is a perspective view showing a conventional molding die on the side of a surface having moldable-material-supplying apertures.
a) is a schematic view showing a work for the conventional molding die.
b) is a schematic view showing the formation of first grooves in the conventional molding die.
c) is a schematic view showing the formation of second grooves in the conventional molding die.
a) is a schematic view showing a conventional die having molding grooves.
b) is a schematic view showing the die of the present invention having molding grooves.
With an outer periphery of a groove-having surface in a shape of polygon having 6 or more corners, such as hexagon or octagon (
The effect of the present invention is large particularly in the case of a large molding die. The effect of reducing the number of machining steps is remarkable when the maximum length of the grooves 30 in the molding die is 150 mm or more, larger when it is 190 mm or more, and much larger when it is 250 mm or more. When the outer peripheral edge of the groove-having surface 31 has a tapered surface 33 as shown in
As the polygonal shape of the outer periphery 32 of the groove-having surface 31 has a larger number of corners like decagon and dodecagon, the percentage of portions of the grooves 30 not used for the extrusion of a honeycomb molding can be reduced. However, this reduces a crossing angle of the outer periphery 32 of the groove-having surface 31 and the grooves 30 in some areas, so that the tool 50 is likely deformed and thus broken. To prevent the tool 50 from being broken, the crossing angle of the outer periphery 32 of the groove-having surface 31 and the grooves 30 should be 30° or more. Because the larger crossing angle of the outer periphery 32 of the groove-having surface 31 and the grooves 30 has a larger effect of preventing the breakage of the tool 50, the crossing angle is preferably 40° or more. Also, the larger crossing angle can reduce the unevenness of a pitch in the grooves 30, which is generated by such small deformation of the tool 50 as not leading to breakage. When each groove 30 in the die has a width of 0.5 mm or less, particularly 0.3 mm or less, the present invention has a large effect. The term “crossing angle” means a smaller angle between two angles at an intersection of the outer periphery 32 of the groove-having surface 31 and a longitudinal centerline of each groove 30.
Because a not-so-worn, almost-brand-new tool 50 has good biting to the outer periphery 32 of the groove-having surface 31, it is less likely that the tool 50 is broken, and that the grooves 30 have uneven pitch. Accordingly, the tool 50 is preferably exchanged to new one before it is much worn, but frequent exchange needs large numbers of tools 50, resulting in increased production cost. It is thus preferable to form guide grooves 34 in the number of 10-30, for instance, on the outer periphery 32 of the groove-having surface 31 before the tool 50 is much worn, as shown in
In order that the crossing angle of the outer periphery 32 of the groove-having surface 31 and the grooves 30 is 30° or more, the groove-having surface 31 of the molding die 20 preferably has an outer periphery 32 in a shape of hexagon, octagon or dodecagon. The outer periphery 32 of the groove-having surface 31 is preferably regular octagon or dodecagon, because a first machining step for forming pluralities of first parallel grooves 30a, and a second machining step for forming pluralities of second parallel grooves 30b crossing the first grooves 30a with the die-forming work 21 rotated by 90° can be conducted under the same conditions. For instance, in the case of the molding die shown in
The polygonal outer periphery 32 of the groove-having surface 31 may have not only sharp corners but also round or chamfered corners. When the round or chamfered corners are machined to form grooves 30, their crossing angle should be 30° or more. Although each side of the polygon may be not only straight but also rounded or waved, the crossing angle of each side and the grooves 30 should be 30° or more.
Although the molding die 20, namely the aperture-having surface 41, has a circular shape in
The present invention will be explained in further detail by Examples below without intention of restricting the present invention thereto.
Prepared was a die-forming work 21 made of alloy tool steel (JIS G4404), which had a groove-having surface 31 having a regular-octagonal outer periphery 32 circumscribed by a circle having a diameter of 240 mm, and an aperture-having surface 41 of 260 mm×260 mm. The die-forming work 21 was drilled by a cemented carbide drill having a diameter of 1.1 mm and a tip angle of 140° from an aperture-having surface 41 to form moldable-material-supplying apertures 40 as shown in
Grooves 30 were formed on the groove-having surface 31 by machining by a rotating tool 50, which was a thin disc grinder having a thickness of 0.25 mm and a diameter of 100 mm. Pluralities of first grooves 30a in parallel with one outer periphery 32 of the groove-having surface 31 were first formed in the die-forming work 21, which was then turned by 90° to form pluralities of second parallel grooves 30b perpendicular to the first grooves 30a. Perpendicular grooves 30a, 30b were 0.26 mm in width and 6.5 mm in depth with a pitch of 1.5 mm. Thus obtained was a molding die 20 having grooves 30 formed in a lattice pattern in the groove-having surface 31 having a regular-octagonal outer periphery 32 as shown in
A molding die 20 was produced in the same manner as in Example 1, except that the shape of the outer periphery 32 of the groove-having surface 31 was changed to regular dodecagon, and that guide grooves 34 were formed before forming the grooves 30 as shown in
A molding die 20 was produced in the same manner as in Example 1, except for changing the shape of the outer periphery 32 of the groove-having surface 31 to a square of 240 mm×240 mm as shown in
A molding die 20 was produced in the same manner as in Example 2, except for changing the shape of the outer periphery 32 of the groove-having surface 31 to a circle having a diameter of 240 mm as shown in
According to the present invention, less grooves not used for extrusion molding are machined, resulting in reduced number of machining steps, and a rotating tool is less likely broken during forming the grooves. Therefore, the time and cost of machining a die for molding a honeycomb structure can be drastically reduced.
Number | Date | Country | Kind |
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2006-293171 | Oct 2006 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2007/071060 | 10/29/2007 | WO | 00 | 4/21/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2008/053854 | 5/8/2008 | WO | A |
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Number | Date | Country | |
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20100003362 A1 | Jan 2010 | US |