The present invention generally relates to automated matchplate molding machines for forming sand molds for use in foundries, and more particularly relates to apparatus in such mold making equipment for filling and stabilizing drag flasks and/or cope flasks.
Foundries use automated matchplate molding machines for forming sand molds. Formed sand molds are subsequently filled with molten metal material, cooled, and then broken apart to release metal castings. There are several prior art systems for this purpose including several prior art systems assigned to the present Assignee, Hunter Automated Machinery Corporation, including U.S. Pat. No. 3,406,738 to Hunter; U.S. Pat. No. 3,506,058 to Hunter; U.S. Pat. No. 4,890,664 to Hunter; U.S. Pat. No. 4,699,199 to Hunter; U.S. Pat. No. 4,840,218 to Hunter; U.S. Pat. No. 6,622,772 to Hunter; and U.S. Pat. No. 7,210,515 to Hunter. The entire disclosures of these patent references are hereby incorporated by reference as the present invention may be incorporated or used in these types of molding systems. Additional reference can be had to these patent references for additional details of the state of the art and to see potential applicability of the present invention. While the foregoing inventions have set forth significant advances and advanced the state-of-art to increase the speed and efficiency in which automated sand molding can occur, there is still further room for improvement in automated molding machinery which is the subject of the present invention.
A general object of the invention is to provide an improved molding machine for forming molds from sand. Exemplary molding devices according to this invention include a support frame, a cope flask for making cope molds, a drag flask for making drag molds, and a pattern plate adapted to be positioned between the cope flask and the drag flask, and typically fixed to the drag flask, for forming patterns in the cope and drag molds. The mold machines include a squeeze station with a squeeze head being received at an open end of the cope flask. The squeeze station includes expandable and retractable actuators, such as pneumatic or hydraulic pistons, mounted between the cope and drag flask and the support frame to drive the cope and drag flask relative to the squeeze head. The molding machine further includes a drag flask filling station horizontally adjacent to the squeeze station. The drag flask is cyclically shifted back and forth between the squeeze station and the drag flask filling station during operation of the molding machine. A hopper car having a sand measuring hopper with a sand discharge outlet is disposed movable above the support frame to add sand to the cope and drag flasks to create the sand molds.
The molding machine support frame according to this invention can include vertical cylindrical frame legs at the squeeze station, and the cope flask is movably mounted on each of the cylindrical frame legs by a cylindrical linear-motion slide. In a similar manner the mold machine squeeze station includes a platen table assembly driven by a hydraulic actuator, wherein the platen table is elevated and carries a drag flask, pattern plate, and mold in contact with a bottom surface of the cope flask and mold in the operational state such that as the drag flask, pattern plate, and cope flask are driven toward the squeeze head, and that is movably mounted on each of the cylindrical frame legs by a cylindrical linear-motion slide. Each cylindrical linear-motion slide can include a cylindrical housing enclosing a cylindrical bearing that extends around an outer circumference of the corresponding vertical frame leg.
In one or more embodiments of this invention, the hopper car shifts horizontally relative to the support frame via one or more linear-motion slides, between the squeeze station for filling the cope flask with sand and the drag flask filling station for filling the drag flask with sand. Each linear-motion slide can include a cylindrical shaft mounted on the support frame or hopper car, and a linear-motion bearing slidably mounted about the cylindrical shaft. The linear-motion bearing is disposed in a bearing housing that is connected to the hopper car or support frame. The linear-motion slide(s) can include a compensation mechanism that allows displacement caused by the movement of the squeeze head to contact upper frame stops of the compensation mechanism during the mold making operation.
The molding machine can include a rotary cradle in the filling station that receives and holds the drag flask during filling. A board feeder can be disposed adjacent the rotary cradle to insert a bottom board over the filled drag flask. In one or more embodiments of this invention, the board feeder including one or more rodless cylinders connected to the support frame for moving the bottom board with respect to the rotary cradle. Each rodless cylinder is desirably pivotally mounted to a board feeder head plate of the board feeder. The board feeder can include a board feeder head plate pivotally mounted on a carriage of the rodless cylinder, such as by a bearing between the board feeder head plate and the carriage. The carriage can be magnetically coupled to a piston that moves within a corresponding cylinder of the rodless cylinder.
In one or more embodiments of the invention, the molding machine includes a spray head, such as for applying a release agent to the pattern plate, disposed in the filling station, and a spray vapor evacuation device disposed adjacent to at least one of the rotary cradle or the spray head. The spray head can include a spray nozzle oriented toward the rotary cradle for spraying the release agent on the pattern plate as it comes into the rotary cradle, and the evacuation device is desirably disposed in or around a spray area between the spray head and the rotary cradle. The evacuation device can include a tube connected to a vacuum source, such as an inline vacuum pump in combination with the evacuation tube. A separation device including at least one of a cyclonic separator or a water separator can also be used in combination with the tube to separate some or all of the captured release agent vapor from the air in the tube. In one embodiment of the invention, the evacuation device additionally or alternatively includes a tube end in combination with a gap formed between an inner plate of the drag flask and the pattern plate, such as for collecting spray vapors near the point of intended contact with the pattern plate.
As shown in
The hopper car 18 linearly reciprocates horizontally along a top portion of the support frame 12, such as by pneumatic or hydraulic pistons, mechanical chain drives, and/or rodless cylinders separate or integral to the linear slides 30. The hopper car 18 automatically shifts back and forth between the mold squeeze and release station 16 and the drag flask filling station 14. This alternately and successively positions the sand hopper 20 at the mold squeeze and release station 16 to fill the cope flask 24 and the drag flask filling station 14 to fill the drag flask 26. The cope flask 24 is always situated at the mold squeeze and release station 16 during all successive molding operations of the machine 10, while the drag flask 26 (and pattern plate 28 which is typically secured thereto) is carted back and forth between the two stations 14, 16. To facilitate the horizontal cycling back and forth between the two stations, rollers 29 are provided upon which the drag flask 26 is adapted to ride and roll between the two stations.
At the drag flask filling station 14, the drag flask 26 is received in a rotary cradle 35 that flips the drag flask 26 upside down such that the open end 44 of the drag flask 26 faces the discharge port 22 of the sand hopper 20 allowing the drag flask 26 to be filled with sand. After the drag flask 26 is filled with sand it can then be turned over again by the rotary cradle 35 to an upright position and then shifted to the mold squeeze and release station 16, where it is assembled with the cope flask. The cope flask 24 is lowered into position by one or more actuators 25 connected between the frame 12 and the cope flask 24. Once in position, the cope flask 24 is then filled with sand, squeezed, and then disassembled to release the formed cope and drag molds 34, 36. Formed molds 34, 36 are then output to downstream mold handling equipment for receipt of molten metal to produce metal castings.
The mold squeeze and release station 16 includes several relatively conventional components including a squeeze head 38 that is adapted to be received in an open end 40 of the cope flask and a platen table 42 which receives a bottom board 43 of the drag flask 44. As shown, the squeeze head 38 and platen table 42 are arranged in opposition relative to each other with sufficient space provided therebetween to receive the mold flask assembly for the formation of sand molds. Preferably the plunging axis is vertically aligned as shown, with the platen table 42 located vertically underneath the squeeze head 38. The platen table 42 is actuated by a platen hydraulic cylinder 46 which is operable to raise and lower the platen table 42. The hydraulic cylinder 46 is also operable to squeeze the cope and drag molds 34, 36 contained in the cope and drag flasks 24, 26 when the flask assembly is assembled to form and compress the cope and drag molds 34, 36. The hydraulic cylinder 46 is also operable to locate the platen table 42 at different elevations to facilitate release of the drag mold 36 and assemblage of the formed drag mold 36 with the cope mold 34.
In one embodiment of this invention, the cope flask 24 and/or the drag flask 26, such as via the platen table 42 and/or hydraulic cylinder assembly, is supported on the frame 12 by linear-motion slides 50, such as shown in
As shown in
In one embodiment of this invention, the board feeder 60 includes one or more rodless cylinders 62 for moving the bottom board 43. As shown in
As shown in
In particular embodiments of the invention, a release agent is applied to the pattern plate 28, such as prior to the drag flask 26 receiving sand. An exemplary release agent is offered under the name FoundaryGeneral® (General Chemical Corp., Brighton, Mich.). The release agent is desirably applied as a spray to the pattern plate 28. As shown in
The collection tube 84 is connected by suitable tubing to a vacuum source 88, which creates a negative pressure in the tube 84, thereby drawing vapor from the spray area 85 into collection tube 84. Any suitable vacuum source or pump can be used as vacuum source 88. In one exemplary embodiment, the vacuum source 88 is or includes an inline vacuum, such as a threaded line vac from Exair (Cincinnati, Ohio). The vacuum source draws the collected vapor and/or fumes into the evacuation device 82, which exhausts the fumes to a desired area or to a collection device 90. The collection device can be a filter and/or other suitable collection or filtration device. In one embodiment of this invention, the collection device 90 is or includes a separation device. Exemplary separation devices include, without limitation a cyclonic separator and/or a water separator, such as a centrifugal water separator. The collection device desirably removes or concentrates the vapor particulate or fumes, thereby reducing or eliminating the vapor or fumes from air exhausted to the environment.
The molding machine 10 includes a support frame 12, defining, at least in part, a drag flask filling station 14 and a mold squeeze and release station 16. The molding machine 10 includes a movable hopper car 18 which includes a sand hopper 20 that is filled with sand. The sand hopper 20 has an openable and closable discharge port 22 which is adapted to align with and discharge sand separately into a cope flask 24 and a drag flask 26. The movable hopper car 18 is attached to the frame by linear slides 30. Each linear slide 30 includes a bearing housing 31 connected to the hopper car 18, and enclosing a linear-motion bearing 32. The bearing moves along cylindrical shaft 33, which is attached to frame 12.
At the drag flask filling station 14, the drag flask 26 is received in a rotary cradle 35 that flips the drag flask 26 upside down, allowing the drag flask 26 to be filled with sand. After the drag flask 26 is filled with sand it can then be turned over again by the rotary cradle 35 to an upright position and then shifted to the mold squeeze and release station 16, via rollers 29, where it is assembled with the cope flask 24. The cope flask 24 is lowered into position by one or more actuators 25 connected between the frame 12 and the cope flask 24.
The mold squeeze and release station 16 includes a squeeze head 38 that is adapted to be received in an open end 40 of the cope flask and a platen table 42 which receives a bottom board 43 of the drag flask 44. The platen table 42 is actuated by a platen hydraulic cylinder 46 which is operable to raise and lower the platen table 42. Each of the cope flask 24 and the platen table 42 assembly is supported on the frame 12 by linear-motion slides 50. The linear-motion slides 50 each includes a generally cylindrical bearing housing 52 enclosing a cylindrical linear bearing that wraps around and travels on one of the vertical, stainless steel, cylindrical frame legs 54 of the frame 12.
During sand filling, the drag flask 26 is positioned within the filling station 14. The drag flask 26 is attached to the pattern plate 28 and inverted by the rotary cradle 35 to position the pattern plate 28 in the downward position to receive sand thereon. The hopper car 18 is positioned as shown in
The board feeder 60 includes one or more rodless cylinders 62 for moving the bottom board 43. As shown in
Thus, the invention a mold machine having improved linear component movement. The invention reduces moving parts, such as through the use of linear bearings and/or rodless cylinders, and provides a vapor evacuation device that improves operator conditions.
The invention illustratively disclosed herein suitably may be practiced in the absence of any element, part, step, component, or ingredient which is not specifically disclosed herein.
While in the foregoing detailed description this invention has been described in relation to certain preferred embodiments thereof, and many details have been set forth for purposes of illustration, it will be apparent to those skilled in the art that the invention is susceptible to additional embodiments and that certain of the details described herein can be varied considerably without departing from the basic principles of the invention.
Number | Name | Date | Kind |
---|---|---|---|
3406738 | Hunter | Oct 1968 | A |
3506058 | Hunter | Apr 1970 | A |
4699199 | Hunter | Oct 1987 | A |
4840218 | Hunter | Jun 1989 | A |
4890664 | Hunter | Jan 1990 | A |
6622772 | Hunter | Sep 2003 | B1 |
7210515 | Hunter | May 2007 | B2 |
Entry |
---|
Aircel A208WS Centrifugal Water Separator, www.ecompressedair.com/filtration/centrifugal-separators (printed Feb. 19, 2013). |
Threaded Line Vac, www.exair.com (printed Feb. 19, 2013). |
Cyclonic separation, http://en.wikipedia.org/wiki/Cyclonic—separation (printed Feb. 19, 2013). |