Die molding machine and pattern carrier

Information

  • Patent Grant
  • 6823929
  • Patent Number
    6,823,929
  • Date Filed
    Thursday, December 20, 2001
    22 years ago
  • Date Issued
    Tuesday, November 30, 2004
    20 years ago
Abstract
A pattern carrier for a flask molding machine including a mount on which a pattern plate is mounted and a flask-shaped, molding flask-removing frame adapted to make contact with a lower end of a molding flask of a flask molding machine and moveable up and down around said pattern plate for removing a finished mold.
Description




TECHNICAL FIELD




This invention relates to a method and apparatus for compressing foundry sand in a molding space. It also relates to a molding machine equipped with a flask and a pattern carrier, wherein upper and lower mold halves are alternately molded for each empty mold half carried therein. In particular, it relates to improvement in the pattern plate carrier with an auxiliary flask carried along with a pattern plate.




BACKGROUND OF THE INVENTION




Conventionally, foundry sand has been compressed in a molding space formed between a pattern plate and molding flask by having the pattern plate and compressing means approach each other. This method has some problems in that since it needs large-sized cylinders the height of a molding machine used for them becomes high and the related facilities, such as a pit, cost a lot accordingly. This method has also some disadvantages in that since in it, wherein an auxiliary flask on which a molding flask is put is put on the upper part of a pattern plate, the foundry sand thrown into the molding space to fill it must be smoothed prior to compression, so that a lot of spilled sand may be generated, and so that uneven compression or an uneven compressed surface may occur. Therefore, a lot of time and labor are needed to deal with such disadvantages. Further, in the conventional blow-squeeze machine, wherein foundry sand is blown into a molding space to fill the space defined by squeeze heads, a molding flask on which an auxiliary flask is put, and a pattern plate, the foundry sand is squeeze compressed.




Japanese Patent Early publication No. 63-63552 discloses a pattern plate carrier with an auxiliary flask as an example used in such a blow squeeze machine. In the conventional pattern plate carrier with an auxiliary flask, a pattern plate is mounted on a carrier box disposed movably up and down such that the auxiliary flask is moved up and down through cylinders fixed to the carrier box. Since to move the auxiliary flask of the thus constituted conventional pattern plate carrier large sized air cylinders having a large diameter are used, a great space is needed as well as a large sized, high priced blow squeeze machine. Further, there is also a problem in that to remove the piping of the air cylinder the replacement of the pattern plate carrier with an auxiliary flask is very troublesome.




DISCLOSURE OF INVENTION




In view of these circumstances this invention was made. Thus, one object of this invention is to supply a method and apparatus for molding foundry sand into a mold with a given uniform hardness in a molding space defined by a pattern plate and flask members without using a pit or large sized oil cylinders.




Another object of this invention is to supply a molding machine and pattern carrier wherein the generation of spills or scraps of sand is reduced, and wherein foundry sand is homogenously compressed at a low cost.




A further object of this invention is to supply a compact pattern plate carrier with an auxiliary flask that can be easily replaced.




In accordance with one aspect, the method of this invention for molding a mold by compressing foundry sand disposed in a molding space defined by a pattern plate, subsidiary flask, and flask member comprises the steps of throwing foundry sand into the molding space, pressing down the foundry sand in the molding space while at least said subsidiary flask is being kept unable to go downward, and further pressing down the foundry sand in the molding space while both said subsidiary flask and said flask members are being kept unable to go downward.




In accordance with a further aspect, the apparatus of this invention for molding a mold comprises a pattern plate fixedly disposed horizontally, a subsidiary flask disposed around said pattern plate so as to be moved up and down, lift means for moving said subsidiary flask up and down, a flask member disposed above said subsidiary flask so as to be moved up and down, and compressing means disposed above said flask member wherein the ends of the compressing members can reach at least a point within said flask member.




In another aspect, the apparatus of this invention for molding a mold comprises a pattern plate disposed fixedly and horizontally, a subsidiary flask disposed around said pattern plate so as to be moved up and down, lift means for moving said subsidiary flask up and down, a flask member disposed above said subsidiary flask so as to be moved up and down, and compressing means disposed above said flask member, wherein the ends of the compressing members can reach at least a point within said flask member.




In still another aspect, the pattern carrier of this invention comprises a mount on which the pattern plate is mounted and a flask-shaped frame disposed to be movable up and down around said pattern plate for removing a finished mold.




In a further aspect, the pattern carrier of this invention comprises a mount on which a pattern plate is mounted, a flask-shaped frame disposed to be movable up and down around said pattern plate for removing a finished mold, a plurality of guide pins for moving said flask-shaped frame up in a parallel manner, and a plurality of actuators mounted on a molding.




In a still further aspect, the pattern plate carrier of this invention for carrying a pattern plate comprises a plurality of upwardly movable cylinders mounted on said pattern plate carrier to move said auxiliary flask, at least two special oil cylinders mounted on said pattern plate carrier for supplying fluid to the upward cylinders by being alternately contracted, and at least two cylinders disposed separately outside said pattern plate carrier and constituted such that the alternate expansion of said at least two cylinders causes said special oil cylinders to alternately contract.











BRIEF DESCRIPTIONS OF DRAWINGS





FIG. 1

is a schematic vertical section to show a first embodiment of the molding machine of this invention.





FIG. 2

is a schematic vertical section to show a state of standby for operating a second embodiment of the molding machine of this invention.





FIG. 3

is a schematic vertical section to show a state of a molding space being defined in the embodiment of FIG.


2


.





FIG. 4

is a schematic vertical section to show a state of the molding space being aeration filled with foundry sand in the embodiment of FIG.


2


.





FIG. 5

is a schematic vertical section to show a state of the foundry sand being primarily compressed in the embodiment of FIG.


2


.





FIG. 6

is a schematic vertical section to show a state of the foundry sand being secondarily compressed in the embodiment of FIG.


2


.





FIG. 7

is a schematic vertical section to show a state of the removal of a finished mold and the supply of foundry sand in the embodiment of FIG.


2


.





FIG. 8

is a schematic vertical section to show a state of the replacement of a pattern plate in the embodiment of FIG.


2


.





FIG. 9

is an enlarged section viewed from an arrowed line A—A in the embodiment of FIG.


2


.





FIG. 10

is an enlarged vertical section to show another embodiment of the pattern plate carrier of this invention.





FIG. 11

is a schematic elevation to show an embodiment of the pattern plate carrier of this invention.











PREFERRED EMBODIMENTS OF INVENTION




Referring to

FIG. 1

, now we explain a first embodiment of the molding machine of this invention. The molding machine comprises a pattern plate


31


fixed horizontally, a lower subsidiary flask


32


that surrounds the periphery of the pattern plate


31


and that is disposed such that it can be both slid and moved up and down, a molding flask


33


that is disposed above the lower subsidiary flask


32


so as to be moved up and down, an upper subsidiary flask


34


disposed above the molding flask


33


so as to be moved up and down, and the squeeze feet


48


of the compressing means


35


, which are disposed so as to be movable up and down above the molding flask


33


such that their ends can reach within an area surrounded by the upper subsidiary flask


34


.




The pattern plate


31


is mounted on the upper surface of a turntable


49


, described below. In the upper surface of the pattern plate


31


, vent-plugs (not shown) are embedded according to the shape of the pattern plate. The lower subsidiary flask


32


, mounted on the turntable


49


, is moved up and down by oil cylinders


36


,


36


that are installed in the turntable as a lift mechanism for the lower flask. The molding flask


33


is moved in the front and rear directions (in relation to the face of the drawing) by a transport mechanism


39


installed in a lift frame


40


that is pivoted onto frames


38


,


38


through a plurality of rollers


37


,


37


with collars. The rollers


33


,


37


are distanced also in the front and rear directions. The lift frame


40


bridges the upper ends of the piston rods of two oil cylinders


42


,


42


that are installed in the left and right ends of a level block like base, and is moved up and down by the expansion/contraction of the oil cylinders.




The upper subsidiary flask


34


bridges the lower ends of the piston rods of downward oil cylinders


44


,


44


installed in the frames


38


,


38


The compressing means


35


, having squeeze feet


48


,


48


, namely, a plurality of compressing members in a square shape, are mounted on rails


50


,


50


that are installed in the frames


38


,


38


such that the compressing feet can be moved in the front and rear directions through a plurality of rollers


51


,


51


with collars. A hopper


52


is mounted on the rails


50


,


50


so that the hopper can be moved in the front and rear directions. The central part of the turntable


49


is installed in the left-side oil cylinder


42


as transport means for transporting the pattern plate in the left and right directions such that the turntable can be intermittently and horizontally rotated.




Below we explain the procedure for compressing foundry sand thrown into a given molding space. First, the lower subsidiary flask


32


is moved up by expanding the oil cylinders


36


,


36


; in this state the oil cylinders


42


,


43


are contracted by a given length; the lift frame


40


is moved down so that the molding flask


33


is put on the lower subsidiary flask


32


; and then the oil cylinders


44


,


44


are expanded such that the upper subsidiary flask


34


is put on the molding flask


33


to form a molding space.




After the formation of the molding space, a given amount of molding sand is thrown into the molding space from the measuring hopper


52


; the hopper


52


is then transported out and at the same time as this the compressing means


35


are transported above the upper subsidiary flask


34


. The downward movement of the lower subsidiary flask


32


is then caused to be unable to be further continued by stopping the discharge of oil when the oil cylinders


36


,


36


are being contracted; the compressing members


48


,


48


of the compressing means


35


are independently moved down while the discharge side of the oil in the cylinders has been released when the oil cylinders


44


,


44


are being contracted; and the compressing means


35


are then moved down by an appropriate height through the lift frame


40


by contracting the oil cylinders


42


,


43


so that the foundry sand is compressed, to thus complete the first stage of the compression.




Next, the downward movement of the lower subsidiary flask


32


is made possible by releasing the discharging side of the oil cylinders


36


,


36


when the cylinders are being contracted; the compressing means


35


, molding flask


33


, and upper subsidiary flask


34


are then moved down by further contracting the oil cylinders


42


,


43


; and then the lower subsidiary flask


32


is thereby moved down through the molding flask


33


, upper subsidiary flask


34


, and oil cylinders


44


,


44


such that the foundry sand united with the molding flask


33


is moved down to be further pressed against the pattern plate, to thus complete the second stage of compression, At this time, preferably the lower surface, namely the joint surface of the foundry sand in the molding flask, coincides with the level of the lower surface of the molding flask.




One cycle of the process of pressing foundry sand is then completed as follows: after the foundry sand has been compressed, the compressing leans


35


, including the compressing members


48


,


48


or the like and the upper subsidiary flask


34


and the like are moved upward by operating the oil cylinders


42


,


43


in an expansion mode while also operating the oil cylinders


36


,


36


in an expansion mode; the molding flask


33


, having a finished mold therein, is raised by being hung up by rollers


37


,


37


, each having a collar, so as to be separated from the pattern plate


31


; another pattern plate


31


is then brought just under the compressing means


35


by horizontally rotating the turntable


49


by 180 degrees; the measuring hopper


52


is filled by foundry sand; and finally, another empty molding flask


33


is put on the transport mechanism


39


to complete the cycle.




Although in the above embodiment a mold with a molding flask is used, a mold with no flask that has just been pushed out from a molding mold may also be used. In this case, the pressing members


48


,


48


can be moved down to any level within the upper subsidiary flask


34


and molding flask, and further, the upper subsidiary flask


34


can be omitted.




Now we explain a second embodiment of this invention by referring to

FIGS. 2-10

.




In

FIG. 2

, upward flask-setting cylinders


2


,


2


are mounted on a molding base


1


, and a frame


3


for supporting the lifting movement of molding members bridges the rods


2


A,


2


A of the cylinders


2


,


2


. A pattern-replacing device


4


for alternatively transporting a pattern carrier


6


,


6


A (see FIG.


9


), on which a pattern plate


5


,


5


A is to be mounted, is disposed above the molding base


1


in a direction perpendicular to the left and right directions of the flask-setting cylinders


2


,


2


. The pattern-replacing device


4


is disposed so as to be movable perpendicular to the face of the drawing by an actuator (not shown).




A pattern carrier


6


,


6


A, on which a pattern plate


5


,


5


A (an upper and lower pattern plates) is to be mounted; is mounted on both sides of the pattern-replacing device


4


such that the pattern carrier


6


,


6


A is in a raised state by about 5 mm through a spring (not shown), and such that the pattern plate


5


,


5


A is alternatively transported into and out relative to a position just above the center of the molding base


1


(see FIG.


9


).




Flask-removing upward cylinders


7


,


7


A, operating as an actuator, are embedded in the four corners of the outside of the pattern plate


5


,


5


A on the pattern carrier


6


,


6


A. Flask-shaped flask-removing frames


8


,


8


A are connected to and supported by the ends of the cylinders


7


,


7


A such that the frames


8


,


8


A can be freely moved up and down while surrounding the pattern plate


5


,


5


A. The flask-removing frames


8


,


8


A are constituted such that at the expanded end of the flask-removing cylinders


7


,


7


A the frames


8


,


8


A protrude a little above the parting plane of the pattern plate


5


,


5


A, and at the contracted end the frames are almost level with the parting plane (see FIG.


6


).




A sand hopper


12


is hung from the support frame


3


. An opening


10


, through which foundry sand is thrown into the hopper, and which is opened and closed by a slide gate


9


, is provided in the upper end of the hopper, and numbers of air chambers


11


,


11


are provided in the inside of the hopper


12


. An air supply tube


21


, through which low-pressure air (for example, 0.05-0.18 Mpa) is introduced communicates with the upper part of the hopper


12


via a changeover valve (not shown) An aeration mechanism is provided in the inside of the lower part of the hopper wherein the air chambers


11


,


11


communicate with a low-pressure ail source (for example, 0,05-0.18 Mpa) via a changeover valve (not shown) such that the low-pressure air is jetted into the hopper


12


to aerate and fluidize the foundry sand S. Further, in the bottom of the hopper


12


segmented-squeeze feet (compressing members)


13


,


13


are provided, and around them nozzles


14


,


14


are provided to direct the sand for filling the hopper.




A subsidiary flask


16


is disposed to surround the segment-squeeze feet


13


,


13


and sand nozzles


14


,


14


. The subsidiary flask


16


is moved up and down through downward subsidiary flask cylinders


17


,


17


installed in the lower part of the hopper


12


. In the upper part of the subsidiary flask


16


vent holes


15


,


15


that communicate with a control chamber (not shown) are disposed to control exhaust air. A transport conveyor


19


for a molding flask


20


is hung from frames


18


,


18


extending, in both the left and right sides of the sand hopper


12


, from the lift frame


3


to the lower part of the squeeze feet


13


,


13


.




Referring again to

FIGS. 2-10

, now we explain the details of the operation of the molding machine of this invention.




In

FIG. 2

; foundry sand is thrown into the sand hopper


12


, all segmented-squeeze feet


13


,


13


together form a concave/convex shape corresponding to that of the pattern plate


5


, and an empty molding flask


20


is post on the transport conveyor


19


.




The pattern carrier


6


is set on the pattern replacing device


4


in a raised state, about 5 mm above the molding base


1


. The mold removing frame


8


is made to protrude above the parting plane of the pattern plate


5


by the subsidiary flask cylinders


7


,


7


. In this state, the subsidiary flask


16


is moved down to closely contact the upper surface of the molding flask


20


by expanding the subsidiary cylinders


17


,


17


after the sand throwing opening has been closed by the slide gate


9


; the molding flask


20


is then pressed against the protruding mold removing frame


8


at the periphery of the pattern plate


5


through the contraction movement of the flask-setting cylinders


2


,


2


; and the pattern carrier


6


is then pushed down in resistance to a spring (not shown), to thus achieve the state as in FIG.


3


. At this time the molding space formed by the pattern plate


5


, mold removing frame


8


, molding flask


20


, subsidiary flask


16


, and squeeze feet


13


,


13


takes a concave/convex shape corresponding to the concave/convex shape of the pattern plate


5


.




The state as in

FIG. 4

is then achieved as follows: low-pressure air is supplied to the sand hopper


12


from the air supply tube


21


via a changeover valve (not shown) while the foundry sand S in the hopper being aerated by low-pressure air is jetted thereinto from numbers of air jet chambers


11


,


11


; and the molding space is thus aeration filled with the foundry sand through the sand directing nozzles


14


,


14


, as shown in FIG.


4


. At this time the remaining low-pressure air used for the aeration filling is discharged through vent holes


15


(not shown) of the pattern plate


5


. Further, the. amount of exhaust air discharged from the vent holes


15


(not shown) of the pattern plate


5


can be controlled by controlling the exhaust air by using an exhaust air control chamber (not shown). This may enable the density of the foundry sand to be partly adjusted to fill a complicated shape of the pattern plate


5


in the molding space.




The state as in

FIG. 5

is then achieved as follows: the lift support frame


3


and the members supported by it are moved down further while the flask-setting cylinders


2


,


2


are being further contracted, and while the subsidiary flask cylinders


17


,


17


are also being contracted; and then the primary squeeze, namely, the first step compression, is carried out until all the lower surfaces of the squeeze feet


13


,


13


become flat, as shown in FIG.


5


. At this time the contraction movement of the flask-setting cylinders


2


,


2


is continued until the compression (squeeze) pressure indicated by a pressure sensor (not shown) has reached a given first set pressure or the position of an encoder (not shown) of the flask-setting cylinders


2


,


2


has reached a given first set position.




The state as in

FIG. 6

is then achieved as follows: the flask-removing cylinders


7


,


7


are caused to be changed into an oil released state and at the same time as this the flask-setting cylinders


2


,


2


are contracted at a pressure higher than the first step pressure such that the molding flask


20


, subsidiary flask


16


, and squeeze feet


13


,


13


are moved down as a unit to secondarily squeeze (second compression) all the foundry sand. Thus, the mold removing frame


8


is moved down by the contraction of the flask-removing cylinders


7


,


7


to a level about the same as that of the parting plane of the pattern plate


5


, as shown in FIG.


6


. Further, in a case where the squeeze pressure does not reach the given second pressure when the mold removing frame


8


has reached the end of the downward movement, a further squeeze is carried out by further contracting the flask-setting cylinders


2


,


2


while the subsidiary flask cylinders


17


,


17


are being contracted.




When the squeeze pressure has reached the given second set pressure, a squeeze-stabilizing timer begins to operate so that the squeeze operation is maintained for a given time. At this time, to correspond to the situation wherein the mold removing frame


8


has not reached the end of the downward movement, the subsidiary flask cylinders


17


,


17


are operated in an expansion mode such that the molding flask


20


is pushed down until the to mold removing frame


8


has reached the end of the downward movement through the downward movement of the subsidiary flask


16


. Thus, the lower surface of the molding flask


20


can be kept at about the same height as the lower surface of the mold at each time.




The state as in

FIG. 7

is achieved as follows: while the molding flask


20


is being compressed, via the mold removing frame


8


, against the subsidiary flask


16


through the expansion operation of the cylinders


7


,


7


, the flask-setting cylinders


2


,


2


are then inversely operated to remove the finished mold; at this time the subsidiary-flask cylinders


17


,


17


are moved up as a unit by being united with the molding flask


20


and the squeeze feet


13


,


13


; the molding flask


20


that has molded a mold is supported and moved upward to be removed via the mold removing frame


8


by the cylinders


7


,


7


and at the same time as this the molding flask is moved up as a unit by being united with a subsidiary flask


16


and squeeze feet


13


,


13


; and in the middle of the upward operation the molding flask


20


that has molded a mold is scooped up by the transport conveyor


19


to be completely separated from the pattern plate, and foundry sand S is supplied to the sand hopper as shown in FIG.


7


. At this time the mold is removed in a very precise manner. This is because the finished mold is removed when it is raised a little from its stationary state, as well as the finished mold being removed when the piston rods


2


A,


2


A of the flask-setting cylinders have been in their most contracted positions.




Finally, the state as in

FIG. 8

is achieved as follows: the molding flask


20


, which has molded a mold, is then transported away via the transport conveyor


19


; an empty molding flask


20


is transported in and at the same time as this the pattern replacing device


4


is operated by actuators (not shown) to replace the pattern plate


5


with a pattern plate


5


A; and the segmented squeeze feet


13


,


13


are operated to form a concave/convex shape corresponding to the concave/convex shape of the pattern plate


5


A, as shown in FIG.


8


.




When the pattern plate


5


,


5


A is to be replaced with another pattern plate, a pattern carrier


6


,


6


A, on which the pattern plate


5


,


5


A is placed, is transported out from the pattern replacing device


4


by pattern carrier transport means (not shown), and after the pattern plate


5


,


5


A has been replaced with another pattern plate, the pattern carrier


6


,


6


A, on which another pattern plate is placed, is transported to be set into the pattern replacing device


4


.




Although in the embodiments of this invention it is described that low-pressure air is jetted from the lower periphery and the lower inside of the sand hopper


12


, the low-pressure air may be jetted from another location in the sand hopper


12


. Although the preparatory compression of foundry sand is not carried out, foundry sand may be preparatively compressed through fluid air compression by providing a rotary gate, or an opening for introducing compressed air, and the like. Further, although it is described that numbers of air jetting chambers


11


,


11


communicate with a changeover valve (not shown), this may be changed such that a changeover valve is provided for each individual air jetting chamber to separately adjust the jetted low-pressure air.




Although in the embodiments of this invention it is described that the flask-removing cylinders


7


,


7


A that operate as an actuator to move the flask-removing frame are built in the pattern carrier


6


,


6


A, the flask-removing cylinders may be not so limited, but they may be built in the pattern replacing device


4


. Further, another embodiment of a pattern carrier


25


, as shown in

FIG. 10

, comprises a portion for placing a pattern plate


22


, a plurality of guide pins


24


that slide up and down on the outside of the pattern plate


22


and that horizontally push up the bottom surface of the flask-shaped mold removing frame


23


, flask-removing cylinders


26


that operate as a plurality of actuators for moving up and down the plurality of guide pins


24


so as to have them penetrate a space portion in the bottom surface of the pattern carrier


25


, and a molding base


27


on which the flask-removing cylinders


26


are mounted such that ends of the flask-removing cylinders


26


do not reach the lower surface of the pattern carrier


25


when they are most contracted.




It is a matter of course that there should be no interference between the pattern replacing device


28


and the flask-removing cylinders


26


when the former is being transferred. Some means (for example, fall preventing means, not shown, that connects the plurality of guide pins


24


to the flask-removing frame


23


) should be provided to prevent the plurality of guide pins


24


from falling. Further, it is considered that in the pattern carrier


25


a clamping member (not shown) and a clamping device to clamp the clamping member are provided, and the pattern carrier


25


is pressed against the molding base


27


by puffing the clamping member through the clamping device.




In the case of the embodiment shown in

FIG. 10

, since the flask-removing cylinders


26


can also be used for upper and lower pattern carriers at both sides of the pattern-replacing device


26


, the cylinders can be installed in just the molding base. Thus, the pattern carrier


25


will not become complicated, and when a working fluid is used, the constitution of its circuit may be simple and the power of the working fluid can be small.




Referring to

FIG. 11

, we now explain an embodiment of the pattern carrier apparatus used for the molding machine of this invention. An auxiliary flask


62


is disposed movably up and down in the upper end part of a box-shaped pattern plate carrier


61


. The auxiliary flask


62


is mounted on the piston rods of a plurality of upward oil cylinders.


63


,


63


mounted on the carrier


61


such that the auxiliary flask


62


can be moved up and down through the expansion/contraction of the oil cylinders


63


,


63


.




The rear lid side of the plurality of oil cylinders


63


,


63


is communicatively connected to the rear lid side of a first special oil cylinder


64


mounted on the left side of the pattern plate carrier


61


via piping


66


, and the front lid side of the plurality of oil cylinders


63


,


63


is communicatively connected to the rear lid side of a second special oil cylinder


65


mounted on the right side of the pattern plate carrier


61


via piping


67


. The expansion and contraction of the plurality of oil cylinders


63


,


63


is generated such that the first and second special oil cylinders


64


and


65


are interlocked to be alternately contracted and expanded so as to alternately supply oil to and discharge oil from, the rear lid side and front lid side, respectively.




The first special oil cylinder


64


is contracted by the expansion of an oil cylinder


68


that is separately and fixedly disposed in a given place outside the pattern plate carrier


61


. The second special oil cylinder


65


is contracted by the expansion of an air cylinder


69


that is separately and fixedly disposed in a given location outside the pattern plate carrier


61


Further, the oil cylinder


68


is expanded/contracted by an oil supply circuit


70


and the air cylinder is expanded/contracted by an air supply circuit


71


On the upper surface of the pattern plate carrier


61


a pattern plate is mounted.




In the thus constituted embodiment the auxiliary flask is moved up such that the pattern plate carrier


61


and the auxiliary flask


62


and the like are moved to a given position; the first special oil cylinder


64


and the second special oil cylinder


65


are made to correspond to the oil cylinder


68


and air cylinder


69


, respectively; and the oil cylinder


68


is expanded and simultaneously the first special oil cylinder


64


is contracted, thereby fluid being supplied to the rear lid side of the oil cylinders


63


,


63


to cause them to expand so as to move up the auxiliary flask


62


. Foundry sand is then blown into a molding space defined by squeeze feet (not shown), a molding flask (not shown), the auxiliary flask


62


, and the pattern plate


72


so that the foundry sand thrown thereinto is compressed to be molded.




After the completion of the molding, the oil cylinder


68


is contracted and simultaneously the air cylinder


69


is expanded, and further, the first special oil cylinder


64


is expanded and simultaneously the second special oil cylinder


65


is contracted. Thereby fluid is supplied to the front lid side of the oil cylinders


63


,


63


and simultaneously fluid is discharged from the rear lid side of the cylinders


63


,


63


to make them contract so as to move down the auxiliary flask


62


.




EFFECTS OF INVENTION




In accordance with the first embodiment of this invention, without the need to install large scale oil cylinders for lifting a pattern plate such as one requiring a pit, almost all the foundry sand in a molding space defined by a pattern plate and molding flask can be surely compressed into a mold having a desired hardness.




In accordance with the second embodiment of this invention, wherein a two step squeeze compression and an increase in the accuracy of removing a flask have been achieved, since the generation of spilled sand and chips of sand is greatly reduced, the molding space can be quantitatively and effectively filled with foundry sand, and since foundry sand is squeezed in correspondence to the concave/convex shape of a pattern plate, a homogenous mold can be molded. Further, since the power of the working fluid and the consumption of compressed air can be reduced, a reduction in cost is realized by saving energy.




In accordance with the pattern carrier of this invention, with the adoption of a flask-removing frame the body of the molding machine is simplified, and since flask-removing cylinders can also be used for both the upper and lower pattern carrier installed in both ends of the pattern replacing device, the simple structure of this invention enables the number of actuators to be halved, to save the power of working fluid.




In accordance with the embodiment of the improved pattern plate carrier of this invention, since the pattern plate carrier with an auxiliary flask can be compact, and since the time and labor for the attachment/detachment of piping can be reduced, the pattern plate carrier with an auxiliary flask can be accurately and movably installed.




As is clear from the above descriptions, the pattern plate carrier molding machine of this invention has various, excellent practical effects.



Claims
  • 1. A pattern carrier for a flask molding machine comprisinga mount on which a pattern plate is mounted and a flask-shaped, molding flask-removing frame adapted to make contact with a lower end of a molding flask of a flask molding machine and moveable up and down around said pattern plate for removing a finished mold.
  • 2. The pattern carrier for a flask molding machine of claim 1, wherein said flask-shaped, molding flask-removing frame is moved up and down by actuators built into said pattern carrier or by a device for replacing the pattern plate.
  • 3. A pattern carrier comprising a mount on which a pattern plate is mounted, a flask-shaped frame disposed movably up and down around said pattern plate for removing a finished mold, a plurality of guide pins for moving said flask-shaped frame up in a parallel manner, and a plurality of actuators mounted on a molding base, wherein said actuators pass through a space in said pattern carrier so as to move said plurality of guide pins up and down and are mounted so as to have their ends not touch a lower surface of the pattern carrier in their most contracted states.
  • 4. The pattern carrier of claim 2 or 3, wherein said actuators are cylinders operated by an operating fluid.
  • 5. The pattern carrier of claim 2 or 3, wherein said actuators are electric cylinders.
  • 6. A pattern plate carrier for carrying a pattern plate, wherein the pattern plate carrier has an auxiliary flask on which a pattern plate is mounted moveable up and down, comprisinga plurality of upward moveable cylinders mounted on said pattern plate carrier to move said auxiliary flask, at least two oil cylinders mounted on said pattern plate carrier for supplying a fluid with the upward cylinders by being alternately contracted, and at least two cylinders disposed separately outside said pattern plate carrier, and constituted such that the mutual expansion of said at least two cylinders causes said respective oil cylinders to alternately contact.
Priority Claims (3)
Number Date Country Kind
2000-120567 Apr 2000 JP
2000-148123 May 2000 JP
2000-171684 Jun 2000 JP
PCT Information
Filing Document Filing Date Country Kind
PCT/JP01/03262 WO 00
Publishing Document Publishing Date Country Kind
WO01/81025 11/1/2001 WO A
US Referenced Citations (3)
Number Name Date Kind
3736978 Taccone Jun 1973 A
4230172 Uzaki et al. Oct 1980 A
4702301 Bühler Oct 1987 A
Foreign Referenced Citations (2)
Number Date Country
3437702 Jun 1985 DE
58-53349 Mar 1983 JP