KR101392355B1 - match-plate molding machine - Google Patents

Abstract

The present invention relates to a molding method for simultaneously separating an upper flask and a lower flask from a match plate. The method includes: maintaining a match plate between upper and lower flasks; Defining an upper molding space and a lower molding space by inserting an upper squeeze member and a lower squeeze member into the openings of the upper and lower flasks opposed to the match plate; Filling the molding space defined above with a molding sand; And driving the upper and lower squeeze members toward the match plate to simultaneously press the molding sand in the upper and lower molding spaces to mold the upper mold and the lower mold simultaneously. The upper and the lower flask having the formed upper and lower molds are simultaneously forced out of the match plate when the flasks are stationary.

Description

{MATCH-PLATE MOLDING MACHINE}

The present invention relates to a molding machine and a molding method, and more particularly, to a molding method using a match-plate molding machine and a match plate.

An example of a match plate molding machine for simultaneously molding conventional upper and lower molds is disclosed in WO2005 / 058528A1. In this molding machine, first, the match plate is held by being fitted in a cope flask and a drag flask. Subsequently, upper and lower squeeze members are inserted into respective flasks through their openings facing the match plate to define upper and lower molding spaces. Then, the defined molding space is filled with molding sand. Thereafter, the upper and lower squeeze members move relative to the match plate to press the molding sand in the molding space to mold the upper mold and the lower mold. Then, the upper and lower flask in which the corresponding upper and lower molds are embedded is separated from the match plate. These separation processes are accomplished by a cylinder that moves the upper and the lower flask forward and backward with respect to the match plate.

This conventional molding machine is troublesome in that the process of separating the upper and the lower flask from the match plate is started when the match plate is attached to the upper mold or the lower mold. That is, when the match plate is attached to any one of the molds, first, the other one of the molds (i.e., the mold not attached to the match plate) and the corresponding flask having the other mold are separated from the match plate , And is then stripped) (first sprouting process). Then, one mold (that is, a mold attached to the match plate) and the corresponding flask in which the one mold is embedded are then simultaneously separated from the match plate (second sprouting process). The first shaping step is initiated when the other template is stationary. However, the second shaping process is performed by moving the mold (the one mold) attached to the match plate while the moving match plate that was moving just before that point is stopped. For this reason, the one template may be subjected to considerable impact when detached from the match plate. Therefore, the second sprouting process can lead to defects.

It is therefore an object of the present invention to provide a molding machine and a molding method which prevent any defects in the mold attached to the match plate when the mold and the corresponding flask in which the mold is embedded are separated from the match plate.

In one aspect of the present invention, there is provided a method of manufacturing a golf club head comprising: holding a match plate between an upper flask and a lower flask; Defining an upper molding space and a lower molding space by inserting an upper squeeze member and a lower squeeze member into the openings of the upper and lower flasks opposed to the match plate; Filling the molding space defined above with a molding sand; And driving the upper and lower squeeze members toward the match plate to squeeze the molding sand in the upper and lower molding spaces, thereby simultaneously molding the upper mold and the lower mold.

The method is characterized by further comprising the step of simultaneously forcing the upper and lower flask having the formed upper and lower molds from the match plate when the flask is stationary.

Preferably, the speed at which the cope flask is separated from the drag flask is twice the speed when the match plate is detached from the drag flask, and the speed at which the flask is separated from the match flask is less than the speed And is preferably equal to the speed at which the flask is separated from the match plate.

In another aspect of the present invention, an upper flask and a lower flask; A match plate held between the flasks; An upper squeeze member and a lower squeeze member insertable into an opening of the upper and the lower flask opposing to the match plate; Means for filling the foundry sand in the upper molding space defined by the upper flask, the match plate and the upper squeeze member and the lower molding space defined by the lower flask, the match plate and the lower squeeze member; And driving means for driving the upper and lower squeeze members toward the match plate so as to press the molding sand in the upper and lower molding spaces so as to simultaneously mold the upper mold and the lower mold.

The molding machine further includes upper and lower pushing means for forcibly pushing the upper and lower flasks having the formed upper and lower molds from the match plate when the flask is stopped, And the pushing means is mounted on both of the upper flask and the lower flask.

Preferably, the upper push means is a hydraulic cylinder extended by the oil inside. The lower push means may be a hydraulic cylinder having less force for feeding the oil pushed into the cylinder than the upper push means, or an air cylinder which is stretched by compressed air, or may be an elastic member member.

In one embodiment of the present invention, the upper and the lower flask have sand-filling ports on their side walls to fill the sand.

Preferably, the drag flask is fixed on a rotating frame which rotates downward and upward in a vertical plane. The upper flask is mounted on the rotating frame so as to be able to move forward and backward with respect to the drag flask.

The molding machine may further include a transport mechanism for inserting and separating the match plate between the upper and lower flasks. The apparatus may further include a mechanism for advancing and retracting the match plate with respect to the drag flask.

The molds in the match plate molding machine of the present invention may be tight-flasks molds or flaskless molds.

These and other objects and advantages of the present invention will become more apparent from the following detailed description with reference to the accompanying drawings.

1 is a front view schematically showing a molding machine of the present invention.

Fig. 2 is a schematic left side view of the molding machine of Fig. 1; Fig.

Fig. 3 schematically shows a pressurizing fluidic unit for driving the molding machines of Figs. 1 and 2. Fig.

Figure 4 schematically shows another embodiment of a hydraulic power unit.

Now, an embodiment of the match plate molding machine of the present invention will be described in detail with reference to Figs. 1 to 3. As shown in Figs. 1 and 2, the molding machine of the present invention includes a turning frame 2 that extends substantially vertically. The pivoting frame 2 is pivotally mounted on the support shaft 1 so as to be movable up and down in a vertical plane around the support shaft 1. A drag flask (4) having a sand filling port on its side wall is mounted to the lower end of the rotating frame (2) through a support member (3). On the left side of the rotating frame 2, a pair of guide rods 5 are attached back and forth with a predetermined gap therebetween and extend substantially vertically. On the guide rod 5, the match plate 7 is slidably mounted vertically through the guide holder 6. Immediately above the guide holder 6 of the guide rod 5, the cope flask 9 having a sand filling port on its side wall is slidably mounted vertically through the guide holder 8. On the left side of the rotating frame 2, the piston rod front end of the downwardly directed vertical cylinder 10 is attached.

The match plate 7 can be carried in and out between the cope flask 9 and the drag flask 4 by any known transport mechanism (not shown). The match plate 7 can be moved forward and backward with respect to the drag flask 4 by an upwardly-directed cylinder (not shown) mounted on the rotary frame 2 in a stretched and contracted state.

The upper flask 9 is mounted on the cylinder 10 and moves upward and downward by the extension and contraction of the cylinder 10 so that the upper flask 9 is advanced and retracted relative to the match plate. Four downward hydraulic cylinders 11 (upper push means) for pushing the cope flask 9 from the match plate 7 are mounted near four corners of the outer circumference of the cope flask 9 have. Similarly, four upward pneumatic cylinders (lower pushing means) 12 for pushing the drag flask 4 from the match plate 7 are located near the four corners of the outer circumference of the drag flask 4 Respectively.

3, the molding machine is provided with a pressurized fluid unit 13 that supplies pressurized oil to the four hydraulic cylinders 11 and supplies compressed air to the four pneumatic cylinders 12 . The pressurized fluid unit (13) includes an oil pressure unit (14) having a hydraulic pump for generating pressurized oil, and a compressor (15) for generating the compressed air. The hydraulic pump of the hydraulic unit 14 includes an upper port and a lower port of the hydraulic cylinder 16 downward through a directional control valve 17 and a shut- And is connected to a lower port.

A pusher plate 19 is fixed to the lower end of the piston rod of the hydraulic cylinder 16. Four hydraulic pushers 21 for pushing and supplying pressurized oil to the respective upper ports of the four hydraulic cylinders 11 through the four pipes 20 are provided below the pusher plate 19, Is abutted against the pusher plate 19. [ Each hydraulic pusher 21 includes an upwardly directed hydraulic cylinder structure. Four pipes 20 are connected to the hydraulic pump of the hydraulic unit 14 through respective four shut-off valves 22. Each lower port of each of the four hydraulic cylinders 11 is connected to the hydraulic unit 14 through a directional control valve 17. Four pneumatic cylinders 12 are connected to the compressor 15 via a directional control valve 23.

In the above-described molding machine, before the state of the apparatus shown in Figs. 1 and 2, the match plate 7 is moved from a molding station (not shown) to the upper flask 9 and the lower flask 4 And is held. Subsequently, upper and lower squeeze members (not shown) are inserted into the corresponding openings of the cope flask 9 and the drag flask 4, which face the match plate 7, to define the upper and lower molding spaces. Then, the cope flask 9, the drag flask 4, the match plate 7 and their associated members, which define the molding space, are rotated in their vertical posture or horizontal posture, (9, 4) through the sand filling port to fill the molding space. Thereafter, the upper and lower squeeze members are driven toward the match plate 7 to press the molding sand in the upper and lower molding spaces, thereby simultaneously manufacturing the upper mold and the lower mold. As a result, the molding machine is in the state shown in Figs.

At the same time, the shut-off valve 18 is opened beforehand to supply pressurized oil to the lower port of the cylinder 16 and the upper port of the four hydraulic pushers 21, thereby retracting the cylinder 16, The hydraulic pusher 21 is stretched. The shutoff valve 18 is then closed and the four shutoff valves 22 are opened so that the pressurized oil from the hydraulic pump of the hydraulic unit 14 is supplied to the four pipes 20 and four hydraulic pushers 21, As shown in FIG. Further, the pressurized oil from the hydraulic pump is supplied to the upper ports of the four hydraulic cylinders 11 to contract them. Then, the four shut-off valves 22 located between the four pipes 20 and the hydraulic unit 14 are cut off.

1 and 2, the cylinder 10 is stretched to raise the cope flask 9, while the other cylinder (not shown) is retracted to raise the match plate 7. In this case, the speed of the cope flask 9 is preferably twice the speed of the match plate 7 when the flask ascends. Subsequently, the directional control valve 17 rotates to extend the cylinder 16 to contract the four hydraulic pushers 21 through the pusher plate 19, thereby pressing the upper port of the four hydraulic cylinders 11 They supply oil and stretch them. At the same time, the directional control valve 23 is rotated to supply compressed air from the compressor 15 to the four pneumatic cylinders 12, thereby extending them. Thus, the four hydraulic cylinders 11 push down the match plate 7, while at the same time the four pneumatic cylinders 12 push up the match plate 7. This allows the upper and lower flask 9, 4, in which the upper and lower molds are embedded, to push each other simultaneously from the match plate 7. Thus, in contrast to the conventional two-step shaping process, the cope flask 9 and the drag flask 4 are simultaneously withdrawn. Thus, this prevents undesirable impacts that could cause defects in the mold associated with the conventional second spiking process (separating the flask from the match plate with the template embedded therein).

In this case, by setting the speed of the cope flask 9 at the time of ascending to be twice the speed of the match plate 7, the upper and lower flasks 9, There is a sufficient space that can be pushed out from each other simultaneously.

Although the molding machine and molding method of the present invention has been described with respect to preferred embodiments thereof, it should be understood that the present invention is intended to cover all the various changes and modifications that may come within the spirit and scope of the appended claims. Therefore, the construction and operation of the match plate molding machine to which the present invention can be applied is not limited to the contents shown and described herein. For example, the match plate, the cope flask and the drag flask may be rotated after the match plate is held between the upper and the lower flask. [0301] Optionally, the match plate may be held between the cope flask and the drag flask after the flask is rotated. Therefore, the timing of holding the match plate and rotating the flask does not limit the present invention. The upper and lower molds formed by the molding machine and the molding method of the present invention may be a flask having a flask or a flaskless mold.

Further, the hydraulic power unit 13 of the molding machine of the present invention is not limited to the embodiment shown in Fig. The hydraulic power unit 13 of Fig. 3 may be replaced with another hydraulic power unit 13A of Fig. 4, for example. 4 is different from the hydraulic power unit 13A in that the hydraulic cylinder 16 and the shutoff valve 18 are removed while the upper port of the hydraulic pusher 21 is connected to the directional control valve 17 And is different from the above-described hydraulic power unit 13 of Fig. The other components of the other hydraulic power unit 13A of Fig. 4 are the same as those indicated by the same reference numerals of the hydraulic power unit 13 of Fig. 3, and a description thereof will be omitted.

Now, the operation of a molding machine employing another hydraulic power unit 13A will be described. First, the molding machine molds the upper and lower molds in the same manner as in the above-described embodiment. As a result, the molding machine is in the state shown in Figs. Then, the four shut-off valves 22 are opened to supply pressurized oil to the four ports 20 and the lower ports of the four hydraulic pushers 21. The pressurized oil is also supplied to the upper ports of the four hydraulic cylinders 11 to shrink them. The four shut-off valves 22 are then closed to shut off the fluid communication between the four pipes 20 and the hydraulic unit 14.

1 and 2, the cylinder 10 is then stretched to raise the upper flask, while the other cylinder (not shown) is retracted to lift the match plate 7. In this case, it is preferable that the speed of the cope flask 9 at the time of ascending is two times the speed of the match plate 7. Then, the directional control valve 17 is rotated so as to contract the hydraulic pusher 21 through the pusher plate 19, thereby supplying pressurized oil to the upper ports of the four hydraulic cylinders 11, thereby stretching them. At the same time, the directional control valve 23 is rotated to supply compressed air from the compressor 15 to the four pneumatic cylinders 12 to extend them. Therefore, the four hydraulic cylinders 11 push down the match plate 7, while the four pneumatic cylinders 12 push up the match plate 7. This causes the cope flask 9 and the drag flask 4 having the upper and lower molds to simultaneously push from the match plate 7 and against each other. Thus, the cope flask 9 and the drag flask 4 are simultaneously withdrawn, as in the above-described embodiment.

Claims (9)

A cope flask 9 and a drag flask 4; a match plate 7 sandwiched between the cope flask 9 and the drag flask 4; An upper squeeze member and a lower squeeze member which are respectively inserted into the openings located on the opposite sides of the match plate 7 in the cope flask 9 and the drag flask 4 against the match plate 7, ,; The upper flask 9, the match plate 7 and the upper molding space defined by the upper squeeze member and the lower flask 4, the match plate 7, and the lower squeeze member Means for filling the molding sand in the lower molding space defined by the molding space; Driving means for driving the upper and lower squeeze members toward the match plate so as to simultaneously squeeze the molding sand in the upper and lower molding spaces and simultaneously mold the upper and lower molds; A driving means (10) for driving the upper flask (9) in an upper direction; And a driving means for driving the match plate (7) in an upward direction, the match plate molding machine comprising: And a plurality of first hydraulic cylinders (11) capable of pressing down the respective match plates (7) in a downward direction by the supply of pressurized oil, Sudan, Further comprising a pressurized fluid unit for supplying and discharging pressurized oil to the plurality of first hydraulic cylinders (11) of the upper push means, The pressurized fluid unit includes: An oil pressure unit 14 having a hydraulic pump and supplying pressurized oil, A second hydraulic cylinder 16 connected to the hydraulic unit 14 through a first valve 17, An upper port connected to the hydraulic unit 14 through a second valve 18 and also connected to a lower port of the second hydraulic cylinder 16 and an upper port connected to the lower port of the second hydraulic cylinder 16, Each of the upper ends of the rods of the first hydraulic cylinder (11) is arranged so as to be movable upward and downward, the first hydraulic cylinder (11) having a lower port connected to each upper port of the hydraulic cylinder A plurality of hydraulic pushers 21 for supplying pressurized oil to respective upper ports of the plurality of first hydraulic cylinders 11 of the upper push means when the upper ends of the rods of the upper push device 11 move downward, , And a pusher plate which is fixed to the second hydraulic cylinder and abuts against the upper ends of the rods of the hydraulic pusher so as to move the upper ends of the rods of the hydraulic pushers in a downward direction, Each of the lower port of the hydraulic pusher 21 and the upper port of each of the plurality of first hydraulic cylinders 11 of the upper push means is connected to the hydraulic unit 14 via the piping and the third valve And pressurized oil from the hydraulic pump is connected to the first valve (22) by operation of the third valve (22) The match plate molding machine further comprises lower push means including a plurality of pneumatic cylinders (12) in which the tops of the rods move upward by the supply of compressed air to press the match plate upwardly , A driving means 10 for driving the cope flask 9 in an upward direction and a driving means for driving the match plate 7 in an upward direction are operated to drive the cope flask 9 and the match plate 7 ) Are respectively moved upward, The first valve 17 of the pressurized fluid unit is operated to actuate the hydraulic pusher 21 via the second hydraulic cylinder 16 so that the plurality of first hydraulic cylinders The upper end of each rod of the plurality of pneumatic cylinders 12 of the lower push means is moved upward by the supply of the compressed air And the upper and lower flasks 9 and 4 including the formed upper and lower molds are simultaneously forced from the speed zero from the match plate 7 by moving the match plate 7 upwardly And the upper and the lower flask (9, 4) are simultaneously pulled out. A cope flask 9 and a drag flask 4; a match plate 7 sandwiched between the cope flask 9 and the drag flask 4; An upper squeeze member and a lower squeeze member which are respectively inserted into the openings located on opposite sides of the match plate 7 in the cope flask 9 and the drag flask 4 so as to face the match plate 7, ; The upper flask 9, the match plate 7 and the upper molding space defined by the upper squeeze member and the lower flask 4, the match plate 7, and the lower squeeze member Means for filling the molding sand in the lower molding space defined by the molding space; Driving means for driving the upper and lower squeeze members toward the match plate (7) so as to simultaneously squeeze the molding sand in the upper and lower molding spaces to simultaneously form the upper and lower molds; A driving means (10) for driving the cope flask upward; And a driving means for driving the match plate (7) in an upward direction, the match plate molding machine comprising: An upper push means including a plurality of hydraulic cylinders (11) capable of pressing the match plates downward by the lower ends of the rods moving downward by the supply of pressurized oil, Further comprising a pressurized fluid unit for supplying and discharging pressurized oil to the plurality of hydraulic cylinders (11) of the upper push means, The pressurized fluid unit includes: An oil pressure unit 14 that has a hydraulic pump and supplies pressurized oil, An upper port connected to the hydraulic unit (14) through a first valve (17) and a lower port connected to an upper port of each of the plurality of hydraulic cylinders (11) of the upper pushing means, Wherein each of the upper ends of the rods of the cylinder 11 is movably arranged in the upward and downward directions and when the upper ends of the rods of the hydraulic cylinder 11 are moved downwardly, the plurality of hydraulic cylinders 11 A plurality of hydraulic pushers 21 for supplying pressurized oil to the respective upper ports of the hydraulic pressers 21, And a pusher plate (19) provided in contact with the upper ends of the rods of the hydraulic pusher (21) Each of the lower port of the hydraulic pusher 21 and the upper port of each of the plurality of hydraulic cylinders 11 of the upper push means is connected to the hydraulic unit 14 via the piping and the second valve 22, The pressurized oil from the hydraulic pump is connected to the second valve 22 by the operation of the second valve 22, The match plate molding machine includes lower push means including a plurality of pneumatic cylinders (12) in which each rod top moves upward by the supply of compressed air to press the match plate (7) upwardly Further, A driving means for driving the cope flask 9 in an upward direction and a driving means for driving the match plate 7 in an upward direction are operated and the cope flask 9 and the match plate 7 are driven When moving in the upward direction, The first valve 17 of the pressurized fluid unit is operated to actuate the hydraulic pusher 21 and the lower end of the rod of the hydraulic cylinders 11 of the upper push means moves the match plate 7 And the upper ends of the rods of the plurality of pneumatic cylinders (12) of the lower push means are moved upward by the supply of the compressed air to press the match plate (7) upward The upper and lower flasks 9 and 4 including the formed upper and lower molds are simultaneously forced from the speed zero from the match plate 7 so that the upper and lower flasks 9 and 4 ) Are formed at the same time. 3. The method according to claim 1 or 2, Wherein the upper and lower flasks each have a sand supply hole on a side wall thereof. 3. The method according to claim 1 or 2, Wherein the drag flask is fixed to a rotating frame which rotates up and down in a vertical plane, and the upper flask is mounted on the rotating frame so as to be movable forward and backward with respect to the drag flask. 3. The method according to claim 1 or 2, Further comprising a transport mechanism for transporting the match plate so as to insert and separate the match plate between the cope flask and the drag flask. 3. The method according to claim 1 or 2, Further comprising a mechanism for advancing and retreating the match plate with respect to the drag flask. 3. The method according to claim 1 or 2, Wherein the upper and lower molds to be molded are a tight-flask mold or a flaskless mold. delete delete

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