KR20180109857A - Molding machine - Google Patents

Abstract

A molding machine for molding a mold using the loaded flask and pattern plate, comprising: a filling frame having a lower opening communicating with an upper opening of the flask and an opened side; a squeeze board capable of entering and exiting the filling frame; A squeeze head mechanism passing through the squeeze board and having a plurality of squeeze feet that can be raised and lowered with respect to the squeeze board; and a molding die formed in the molding space defined by the flask, the filling frame, the squeeze head mechanism, A sand filling hopper having at least one sand filling port for filling the sand filling port and a sand filling nozzle formed in a member detachably mounted on an opening of a side portion of the peeling frame and communicating the sand filling port with the molding space do.

Description

Molding machine

The present disclosure relates to a mold making machine for molding a mold by squeezing a filled mold sand filled in a mold.

BACKGROUND ART Conventionally, a mold making machine for filling a casting mold in a flask by aeration and squeezing the filled casting mold to form a mold has been known (see, for example, Patent Document 1).

Patent Document 1: Japanese Patent Application Laid-Open No. 2002-1491

However, in the cast molding machine disclosed in Patent Document 1, there is a portion to be worn out depending on the use period and the frequency of use. Worn parts may affect the quality of the casting or casting product. In the field of the art, there is a demand for a molding machine for molding excellent molds.

A mold-shaping machine according to one aspect of the present invention is a mold-shaping machine for molding a mold by using a loaded flask and a pattern plate, wherein the lower mold has a lower opening connectable with the upper opening of the flask, A squeeze board capable of entering and exiting the filling frame, and a plurality of squeeze feet that can pass through the squeeze board and can be lifted relative to the squeeze board, A sand having a squeeze head mechanism and at least one sand filler filling a molding space formed by the flask, the filling frame, the squeeze head mechanism, and the pattern plate; A fill hopper, and a member removably mounted on an opening in a side portion of the peeling frame, the sand filling port and the molding space And a sand filling nozzle for allowing communication therewith.

According to the mold-molding machine according to one aspect of the present invention, even when the sand filling nozzle is worn, only the member having the sand filling nozzle can be replaced. Therefore, this cast molding machine is excellent in water retention and availability.

A mold-shaping machine according to another aspect of the present invention is a mold-shaping machine for molding a mold using a loaded flask and a pattern plate, comprising: a filling frame having a lower opening connectable with an upper opening of the flask; A filling frame having a lower opening communicating with an upper opening of the peeling frame, and a squeeze board which is insertable into the filling frame, and a plurality of squeeze boards which can pass through the squeeze board, A sand filling hopper having a squeeze head mechanism having a foot and at least one sand filling port for filling the molding space formed by the flask, the filling frame, the filling frame, the squeeze head mechanism and the pattern plate, And a charging device which is formed on a side of the filling frame, And a sand filling nozzle for enabling the space to communicate with each other.

According to another aspect of the present invention, even when the sand filling nozzle is worn, only the filling frame having the sand filling nozzle can be exchanged. Therefore, this cast molding machine is excellent in water retention and availability.

In one embodiment, the mold-molding machine may include a frame-shaped frame forming a part of the molding space, surrounding the periphery of the pattern plate, sliding up and down, and a liner detachable from the inner side of the frame-shaped frame Okay. In this case, the liner disposed between the frame-shaped frame and the pattern plate can reduce wear of the frame-shaped frame and the pattern plate.

In one embodiment, the material of the upper and the inner surfaces of the liner may be urethane rubber. In this case, the abrasion can be further reduced.

In one embodiment, the heat-resistant temperature of the urethane rubber may be 70 to 90 占 폚. In one embodiment, the heat-resistant temperature of the urethane rubber may be 110 to 130 占 폚.

According to various aspects of the present invention, it is possible to provide a mold molding machine for molding an excellent mold.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a longitudinal sectional view showing a state before the start of a mold making machine of the embodiment (home position). FIG.
Fig. 2 is a longitudinal sectional view of the casting mold showing a state in which a molding space is formed. Fig.
3 is a longitudinal sectional view of a casting mold showing a state of aeration charging of a casting mold.
4 is a longitudinal sectional view of the casting mold showing the primary squeezing state of the main crimper.
5 is a longitudinal sectional view of a mold-making machine showing a secondary squeeze state of the main crimper.
6 is a longitudinal sectional view of the casting mold showing the casting mold and the casting mold of the casting mold.
Fig. 7 is a longitudinal sectional view of the casting mold showing a state in which the pattern plate (pattern carrier) has been exchanged. Fig.
FIG. 8 is an enlarged longitudinal sectional view of a sand filling nozzle and a sand filling port on the left side in FIG. 2; FIG.
9 is a partially enlarged longitudinal sectional view showing another embodiment of the frame-shaped frame.
10 is a partial enlarged longitudinal sectional view showing another embodiment in which a molding space is formed;
11 is a sectional view of a peeling frame according to a modification.

Hereinafter, a cast molding machine according to the present embodiment will be described with reference to the drawings. 1 is a longitudinal sectional view showing a state before the start (home position) of the casting mold machine 100 of the embodiment. 2 is a longitudinal sectional view of the casting mold 100 showing a state in which a molding space is formed. The molding machine 100 is a molding machine for molding a mold using the loaded flask and the pattern plate.

As shown in Figs. 1 and 2, the cast molding machine 100 is provided with, for example, a base frame 1. On the base frame 1, a fixed stopper 2 is fixed. On both right and left sides (see Fig. 1) of the molding base 3 composed of the base frame 1 and the fixed stopper 2, the frame set cylinders 4 and 4 are provided standing upwards. Below the one of the frame set cylinders 4 and 4 (left side in Fig. 1), the central portion of the pattern changing apparatus 5 is rotatably supported in the horizontal plane. The main set axis (rotation axis) of the pattern changing device 5 is also used by the frame set cylinder 4 on the left side in Fig.

The pattern exchanging apparatus 5 is a device for carrying in the pattern plate 8. The pattern exchanging apparatus 5 is provided with a main shaft and a plurality of support units (not shown) of the turntable 7 and the pattern carriers 6, 6A. The turntable 7 is rotatably supported on the main shaft in a horizontal plane so that the pattern carriers 6 and 6A are alternately carried in and out of the center of the molding base 3. The turntable 7 is rotated by an actuator (not shown). The actuator is, for example, a hydraulic cylinder. The plurality of support units are mounted on the placement portions of the pattern carriers 6 and 6A in the turntable 7. [

The pattern carrier 6 includes a frame 9, a plurality of guide pins 10, a main frame 11, and a pressing means (not shown). The frame-shaped frame 9 surrounds the outer periphery of the pattern plate 8 and slides up and down. The plurality of guide pins (10) are connected to the lower portion of the frame (9). In the main body frame 11, the guide pin 10 is inserted so as to be able to slide up and down, and the pattern plate 8 is placed on the upper surface. Both ends of the pressing means are hooked on the frame-shaped frame 9 and the main body frame 11, and apply a pressing force in a direction to lower the frame-shaped frame 9. The pressing means is, for example, a plurality of tension coil springs. The pattern carrier 6A has the same configuration as that of the pattern carrier 6.

On the center of the molding base 3, a hydraulic cylinder (oil adhesion cylinder) 14 is disposed. The hydraulic cylinder 14 has an engagement head 13 connected to the upper end of the piston rod. The engaging head 13 is engaged with the engaging groove 12 formed at the lower end central portion of the pattern carriers 6, 6A. In addition, on the molding base 3, a plurality of lifting cylinders 15 are disposed under the plurality of guide pins 10. [ The elevating cylinder 15 lifts the frame-shaped frame 9 via the guide pin 10. The rod head 16 is connected to the upper end of the piston rod of the lifting cylinder 15.

The upper surface of the frame-shaped frame 9 protrudes slightly upward (for example, 30 mm) from the separation surface of the pattern plate 8 when the lifting cylinder 15 is an extended end (see FIG. 2 The upper surface of the frame 9 is substantially flush with the separating surface of the pattern plate 8 when the lifting cylinder 15 is contracted (see Fig. 1).

A lifting support frame 17 is provided between the upper ends of the piston rods 4A of the frame set cylinders 4, A plurality of sand filled hopper elevating cylinders 18 are mounted on the elevating support frame 17. The tip of the piston rod of the sand filled hopper lifting cylinder 18 is connected to the sand filling hopper 19.

The sand filling hopper 19 is provided at its upper end with a sand inlet 21 which is opened and closed by a slide gate 20. The sand filling hopper 19 is provided with a feed pipe 23 through which a low pressure air (for example, 0.05 to 0.18 MPa) is introduced via an open / close valve 22 to an upper portion thereof It is communicated. The lower portion of the sand filled hopper 19 is composed of a bifurcated chute 24. On the inner surface of the chute 24, a plurality of air ejection chambers 25, 25 communicating with a compressed air source (not shown) via an opening / closing valve (not shown) is disposed.

A low pressure air (for example, 0.05 to 0.18 MPa) is blown into the sand filling hopper 19 from the plurality of air ejection chambers 25 and 25 to constitute aeration to float the primary sand S . A sand filling port 26 is provided at the lowermost portion of the chute 24 in the sand filling hopper 19.

A filling frame 27 is fixedly disposed inside the lower portion of the shoot 24. The filling frame 27 has a lower opening 27c connectable to the upper opening 33a of the flask 33. [ A sand filling nozzle 28 is formed on a lower portion (side portion) of the peeling frame 27. One end of the sand filling nozzle 28 communicates with the sand filling port 26, and the other end communicates with the molding space described later. On the inside of the peeling frame 27, a squeeze head mechanism 29 is disposed. The squeeze head mechanism 29 includes a squeeze board 30 and a plurality of squeeze feet 31 that can be put into and out of the peeling frame 27. The plurality of squeeze feet 31 are of a segment type and are mounted through the squeeze board 30 to control the elevation stop of the squeeze board 30. [ The upper end of the squeeze board 30 is fixed to the lower end of the elevating support frame 17. The above-described peeling frame 27 surrounds the outer periphery of the squeeze-head mechanism 29 in a vertically movable manner. The squeeze head mechanism 29 is surrounded by a sand filling hopper 19. [ The squeeze-head mechanism 29 is surrounded by sand filling hoppers 19 from at least two directions.

The carry-in / out conveyor 34 of the flask 33 is suspended from the lifting support frame 17 via a carry-in / out frame 32 extending to the lower position of the squeeze head mechanism 29. The flask 33 is carried in and out by the carry-in / carry-out conveyor 34.

As described above, the squeeze-head mechanism 29 is supported by the two frame set cylinders 4 and 4, and the squeeze-head mechanism 29 is lowered to perform the frame setting process and the squeezing process.

The operation of the molding machine 100 constructed as described above will be described. The state shown in Fig. 1 is a state in which the crown S is put in the sand filled hopper 19 and the empty flask 33 is carried in the carry-in / out conveyor 34. [ The pattern carriers 6 and 6A are fixed to the pattern exchanging apparatus 5 by a compression spring (not shown) in a supporting unit (not shown) while being lifted up about 5 mm from the molding base 3, Lt; / RTI > Fig. 1 shows a state in which the pattern carrier 6 is brought into the upper center of the molding base 3. Fig. There is a gap of about 5 mm between the upper surface of the fixed stopper 2 of the shaping base 3 and the lower surface of the pattern carrier 6.

The engagement grooves 12 formed in the lower central portion of the engaging head 13 and the pattern carrier 6 are formed by lowering the engaging head 13 by contracting the hydraulic cylinder 14 in the state shown in Fig. It is caught. Then the pattern carrier 6 is pulled down against the unillustrated compression spring and the lower surface of the pattern carrier 6 is pressed onto the upper surface of the fixed stopper 2 of the molding base 3. Thereafter, the lifting cylinder 15 is stretched to raise the frame-shaped frame 9 via the guide pin 10. As a result, the upper surface of the frame-shaped frame 9 is projected slightly upward from the separation surface of the pattern plate 8.

In the molding machine for setting the frame from the bottom to the top, the pattern carrier 6 is lifted by the table at the start of the frame setting process. In the lifting step, if the deceleration step is provided so as not to cause the impact, the cycle time may become longer. In the mold-molding machine 100 of the present embodiment, the pattern carrier 6 is pressed onto the fixed stopper 2 by the hydraulic cylinder 14 at the start of the mold setting process, and at the same time, You can lap the action. Therefore, the cycle time can be shortened by the time required for the deceleration process because there is no deceleration process at the start of the process as compared with the conventional molding machine for setting the mold from the bottom to the top.

After the slide gate 20 is operated to close the sand inlet 21, the frame set cylinders 4 and 4 contract. As a result, the flask 33 is placed on the upper surface of the frame 9 projecting upward from the outer periphery of the pattern plate 8. Further, the sand filled hopper lifting cylinder 18 is operated to extend. As a result, the sand filling hopper 19 and the peeling frame 27 are lowered, and the peeling frame 27 is pressed against the upper surface of the flask 33 and brought into close contact with each other. In addition, the squeeze foot 31 operates respectively. Concave and convex are formed relative to the concavities and convexities of the lower pattern plate 8, and the state shown in Fig. 2 is obtained. At this time, a molding space is formed by the pattern plate 8, the frame frame 9, the flask 33, the filling frame 27 and the squeeze head mechanism 29 placed on the pattern carrier 6 And the other end of the sand filling nozzle 28 communicates with the molding space.

Next, the sand is filled by aeration. 3 is a longitudinal sectional view of the casting mold 100 showing the state of the aeration of the casting mold. First, low pressure air is ejected from the plurality of air ejection chambers 25, 25 into the sand filling hopper 19. As a result, the stencil S in the sand filling hopper 19 is suspended in fluidization. In this state, the low-pressure air is supplied from the air supply pipe 23 to the sand filling hopper 19 via the opening / closing valve 22. By the low-pressure air, the template S is charged into the molding space via the sand filling port 26 and the sand filling nozzle 28 (aeration charging). At the time of aeration charging, the low-pressure air is exhausted from a not-shown head hole of the pattern plate 8 or the like.

Next, the frame set cylinders 4 and 4 are further contracted. As a result, the sand filled hopper lifting cylinder 18 is contracted. The frame set cylinders 4 and 4 lower the elevation support frame 17 and the members (the squeeze head mechanism 29, the loading / unloading frame 32, the loading / unloading conveyor 34, etc.) . As described above, the squeeze foot 31 is subjected to the first squeezing of the primary stitch S until the entire surface becomes flat, and the state shown in Fig. 4 is obtained. 4 is a longitudinal sectional view of the casting mold 100 showing the primary squeezing state of the casting mold. At this time, the shrinking operation of the frame set cylinder 4 is performed until the squeeze pressure reaches a set pressure of the first squeeze by a pressure sensor (not shown) (Not shown) reaches the set position of the first squeeze.

Next, the working fluid in the lifting cylinder 15 is switched to a relief state. Then, the frame set cylinders 4, 4 are contracted to operate at a higher pressure than the first squeeze. As a result, the flask 33, the filling frame 27, the sand filling hopper 19, and the squeeze-head mechanism 29 descend in unison to perform secondary squeezing of the entire primary crotal S. 5 is a longitudinal sectional view of the casting mold 100 showing the secondary squeeze state of the casting crimp. The frame shape frame 9 is lowered by the contraction of the lifting cylinder 15 and becomes substantially the same height as the upper surface of the frame frame 9 and the separation surface of the pattern plate 8. [ In this case, the strength of the peripheral portion of the mold is increased, and uniform mold strength can be obtained. When the squeeze pressure does not reach the set pressure of the second squeeze at the time when the frame-shaped frame 9 reaches the descending end, the sand filling hopper elevating cylinder 18 is contracted while the frame set cylinder 4 , 4) are further contracted to perform squeezing.

Next, when the squeeze pressure reaches the set pressure of the second squeeze, the squeeze stability timer is activated, and the squeeze is maintained for a predetermined time. At this time, in order to cope with the case where the frame-shaped frame 9 does not reach the descending end, the sand filling hopper lifting cylinder 18 is extended to lower the filling frame 27, The flask 33 is pushed down until it reaches the descending end. As a result, the lower surface of the flask 33 and the lower surface of the mold can be made almost the same surface each time.

Next, while the lifting cylinder 15 is stretched to push the flask 33 against the peeling frame 27 via the guide pin 10 and the frame frame 9, the frame set cylinders 4 and 4 ) Is operated in the opposite direction to perform a releasing operation. At this time, the flask 33, the filling frame 27, the sand filling hopper 19, and the squeeze head mechanism 29 are integrally raised. Thereafter, the flask 33 molded with the mold is pulled up by the lifting cylinder 15 via the guide pin 10 and the frame-shaped frame 9. Then, the peeling frame 27, the sand filling hopper 19, and the squeeze head mechanism 29 are lifted. In the middle of the ascension, the flask 33 molded with the mold is raised by the carry-in / out conveyor 34 and completely separated from the pattern plate 8. At this time, the filling frame 27 and the sand filling hopper 19 are raised by the shrinking operation of the sand filling hopper elevating cylinder 18. Then, after the slide gate 20 is operated in reverse to open the sand inlet 21, the main saddle S is fed into the sand filling hopper 19 and the state shown in FIG. 6 is obtained. 6 is a longitudinal sectional view of the casting mold 100 showing the casting mold and the casting state of the casting mold. At this time, the molded mold is slightly raised from the stationary state together with the flask 33 and is molded. Then, the piston rod 4A of the frame set cylinder 4 is molded in the most contracted state. As a result, a high sprung accuracy can be realized.

Next, the elevating cylinder 15 is contracted to lower the guide pin 10 and the frame-shaped frame 9. At this time, a plurality of tension coil springs (not shown) apply a pressing force in a direction in which the frame-shaped frame 9 descends, so that the frame-shaped frame 9 can be reliably lowered to the lowered end. The compression spring (not shown) in the support unit (not shown) moves the pattern carrier 6 to the shaping base 3 by lifting the hydraulic cylinder 14 to raise the engagement head 13. [ So that the clamping of the shaping base 3 to the fixed stopper 2 is released.

Next, the flask 33 molded with the mold is taken out via the transfer-in / out conveyor 34, and the empty flask 33 is carried in. In addition, the pattern exchanging apparatus 5 is operated by an actuator (not shown), and the pattern plate 8 and the pattern plate 8A are exchanged. 7 is a longitudinal sectional view of the casting mold 100 showing a state in which the pattern plate (pattern carrier) is exchanged. The above operation is repeated. The pattern exchanging device 5 may be moved by lifting the pattern carriers 6 and 6A by a lifter with a driving roller (not shown) at a station outside the shaping base 3 of the turntable 7, It is also possible to exchange the pattern plates 8, 8A by taking in and out the pattern carriers 6, 6A in the left and right or front and back directions. According to this, it is possible to exchange molds during molding, and it is possible to replace the molds.

In the casting mold machine 100 described above, a sand filling nozzle 28 communicating with the molding space is formed in the peeling frame 27, and the mold is filled from the side of the molding space. Therefore, the mold-molding machine 100 can employ the layout of the squeeze foot 31 determined from the viewpoint of uniform compression as a whole without considering the arrangement of the sand filling nozzles 28. For example, it is possible to arrange the squeeze foot 31 around the flask 33, and more uniform mold strength over the entire surface of the squeeze board can be obtained. Therefore, this casting mold machine 100 can mold an excellent mold.

Next, the details of the sand filling nozzle 28 and the sand filling port 26 will be described. 8 is an enlarged view of the sand filling nozzle 28 and the sand filling port 26 on the left side in Fig. 2 showing a state in which a molding space is formed. Since the sand filling nozzle 28 and the sand filling port 26 on the right side are symmetrical in the left-right direction, the description is omitted.

The sand filling nozzle 28 is formed in the peeling frame 27. The sand filling nozzle 28 is inclined to be lowered from an inlet formed on the outer side surface 27a of the peeling frame 27 toward an outlet formed on the inner side surface 27b. According to this configuration, the cyan mold S is charged from the inclined upper portion with respect to the pattern plate 8. This means that the charged template S is less likely to collide with the squeeze foot 31 having irregularities on the concave and convex portions of the pattern plate 8, There is an advantage. In addition, an exchangeable peeling frame liner can be mounted on the inner surface of the peeling frame 27. A material such as urethane may be used in addition to a steel material such as stainless steel as a whole. In this case, wear of the peeling frame can be prevented.

In addition, in the sand filling nozzle 28, the inclination angle (30 degrees in this embodiment) of the ceiling face 28a is larger than the inclination angle (15 degrees in this embodiment) of the bottom face 28b. According to this configuration, since the squeezing force from the lateral direction is hardly applied to the primary scanning yarn S in the sand filling nozzle 28, the primary scanning yarn S in the sand filling nozzle 28 is more compressed There is an advantage that it is difficult. In addition, there is an advantage that the crown S in the sand filling nozzle 28 is less likely to fall.

The sand filling port 26 has an inclined bottom surface 26a. According to this configuration, there is an advantage that it is easy to introduce the crockery S passing through the sand filling port 26 into the sand filling nozzle 28. The inclination angle of the bottom surface 26a is larger than the inclination angle of the bottom surface 28b of the sand filling nozzle 28 and is 30 degrees in the present embodiment.

In addition, the material of the surface of the bottom surface 26a of the sand filling port 26 is made of ultrahigh molecular weight polyethylene (for example, "Saxin New Right" manufactured by Soshin Kogyo Co., Ltd.). According to this configuration, there is an advantage that the adhesion of the curable resin sheet S to the bottom surface 26a is suppressed and the deposition of the curable resin sheet S can be prevented. In the embodiment, the block member 35 obtained by processing the ultrahigh molecular weight polyethylene material is arranged at the lowermost portion of the chute 24 so that the surface of the bottom surface 26a becomes ultrahigh molecular weight polyethylene. Further, in the embodiment, the sand filling nozzle 28 is mounted on the side surface of the peeling frame and can be replaced. In some cases, a resin such as high-molecular polyethylene having a high abrasion resistance as a whole is used in addition to a steel material as a whole. In some cases, the abrasion resistant material is sprayed on the steel material. With these, it is possible to maintain the formability and to prevent the wear of the nozzle.

In the casting mold machine 100 according to the embodiment, the filling frame 27 is fixed to the inside of the chute 24 in the form of a bifurcation. According to this configuration, since the peeling frame 27 is lifted and lowered together with the sand filling hopper 19 by the sand filling hopper lifting cylinder 18, an actuator for directly lifting the peeling frame 27 itself is not required. Therefore, there is an advantage that the number of actuators can be reduced.

The mold carrier 6 according to the embodiment is provided with the frame-shaped frame 9 in which the pattern carrier 8 surrounds the outer periphery of the pattern plate 8 and slides up and down. However, the present invention is not limited to this. For example, the frame shape frame 9 may be omitted. As shown in the above embodiment, the pattern carrier 6 is provided with the frame-shaped frame 9, and the pattern plate 8, the frame-shaped frame 9, (Squeeze from the side of the model surface) becomes possible when the molding space is formed by the molding frame 33, the peeling frame 27 and the squeeze head mechanism 29.

The frame-shaped frame 9 is not limited to those shown in the above-described embodiments. Next, another embodiment of the frame-shaped frame will be described. Fig. 9 is a partially enlarged view showing another embodiment of the frame-shaped frame, showing only one side of the left-right symmetry. The upper surface of the frame-shaped frame protrudes 30 mm above the separation surface of the pattern plate 8.

As shown in Fig. 9, the frame-shaped frame 36 has a liner 37 which is detachable from its inner side. The liner 37 surrounds the outer periphery of the pattern plate 8 and slides up and down. The liner 37 has a structure in which a urethane rubber 39 is fixed to the metal member 38. 9, the material of the upper end surface and the inner side surface of the liner 37 is made of urethane rubber 39. As shown in Fig. The lower surface of the flask 33 and the urethane rubber 39 of the upper surface of the liner 37 come into contact with each other when the male mold S is charged into the molding space. And the sealing property of the upper surface of the frame frame 36 is improved, and there is an advantage that leakage of the coded sheet S can be prevented. The urethane rubber 39 on the inner side of the liner 37 also has the advantage of being able to improve the abrasion resistance of the outer surface of the liner 37 and the sliding surface of the pattern plate 8. When the liner 37 having the top face and the inside face can not be attached to the pattern carrier 6, it is possible to mount a liner having a sectional I-shape only on the outer periphery of the pattern plate 8. In this way, wear of the outer periphery of the pattern plate 8 can be prevented.

The heat-resistant temperature of the urethane rubber 39 may be, for example, 70 to 90 占 폚. In this embodiment, the heat-resistant temperature of the urethane rubber 39 is 80 占 폚. However, when it is assumed that the temperature of the flask 33 is higher than usual, the heat-resistant temperature of the urethane rubber 39 may be 110 to 130 占 폚. As an example, the heat-resistant temperature of the urethane rubber 39 is 120 占 폚.

In the casting mold machine 100 according to the embodiment, the block member 35 obtained by processing the ultrahigh molecular weight polyethylene material is disposed at the lowermost portion of the chute 24, but the present invention is not limited thereto. For example, the air jetting chamber 25 may be disposed instead of the block member 35, and the low pressure air may be ejected from the bottom surface 26a of the sand filling port 26. [

Further, in the casting mold machine 100 according to the embodiment, sand filling by low-pressure air enables uniform sand filling. The sand filling by the low-pressure air is lower in pressure (for example, 0.05 to 0.18 MPa) than the sand filling (for example, 0.2 to 0.5 MPa) by the blowing method and the sand is charged at low speed. It has the characteristic that it is small.

In the sand filling by the blowing method, the filling rate of the sand is fast, and in particular, the blocking phenomenon occurs in the pocket portion, so that the filling property of the sand is lowered. On the other hand, in the mold-making machine 100 according to the present embodiment, the charging speed of the sand is slowed by the electric pneumatic high-regulating valve at the initial stage of the low- It is also possible to set the charging time to be short by increasing the pressure and increasing the pressure from the middle. If the pressure is low, the charging speed becomes slow, and the charging time of the sand takes time, which may increase the cycle time. In order to achieve high-speed molding and also to reduce wear, it is preferable that the charging speed of the low-pressure air be initially slowed and the charging be performed at a high speed from the middle.

In the casting mold machine 100 according to the above embodiment, the sand filling nozzle 28 is provided in the peeling frame 27. However, in another embodiment, as shown in Fig. 10, the sand filling nozzle 28 may be provided in the charging frame BF separately provided from the filling frame 27. Fig. By doing so, it is possible to provide the vent hole of the low-pressure air in the peeling frame 27 (not shown), and the low-pressure air can be discharged therefrom. In addition, one sand filler is fine.

In the above-described embodiment, the sand filling nozzle 28 is directly formed on the peeling frame 27, but it is not necessary to form the sand filling nozzle 28 directly on the peeling frame 27. For example, an opening may be formed on the side of the peeling frame 27, and a sand filling nozzle 28 may be formed on the member mounted on the opening. 11 is a sectional view of a peeling frame 27A according to a modified example. As shown in Fig. 11, openings 27d and 27e are formed in the side portions on both sides of the peeling frame 27A according to the modified example. Members 50A and 50B are detachably attached to the openings 27d and 27e, respectively. Sand filling nozzles 28A and 28B are formed in the members 50A and 50B, respectively.

When the sand filling nozzles 28A and 28B are worn, the members 50A and 50B need to be replaced, and it is not necessary to replace the entire filling frame. Therefore, this cast molding machine is excellent in water retention and availability.

The members 50A and 50B can be formed of a material (such as resin) having high abrasion resistance such as urethane in addition to a steel material such as stainless steel. As described above, the members 50A and 50B may be formed of a material that is resistant to abrasion, and the filling frame 27A may be formed of a material suitable for molding. In addition, a low-pressure air outlet 27f can be provided in the filling frame 27A. Thereby, since the low-pressure air can be exhausted from the exhaust port 27f, there is an effect that the filling is more excellent.

6, 6A - pattern carrier 8, 8A - pattern plate
9, 36 - Frame Shape Frame 19 - Sand filling hopper
24 - Suit 26 - Sand filling
26a - bottom 27 - peeling frame
27a - Outer side 27b - Inner side
28, 28A, 28B - sand filling nozzle 28a -
28b - bottom 29 - squeeze head mechanism
33 - Spindle 37 - Liner
39 - urethane rubber 50A, 50B - member
100 - Molding machine BF - Charging frame

Claims (6)

A mold-making machine for molding a mold by using a loaded flask and a pattern plate,
A filling frame having a lower opening connectable with an upper opening of the flask and an opened side,
A squeeze board capable of entering and exiting the filling frame and a squeeze head mechanism having a plurality of squeeze feet which can pass through the squeeze board and can be elevated with respect to the squeeze board;
A sand filling hopper having at least one sand filling port for filling a molding space formed with the flask, the filling frame, the squeeze head mechanism, and the pattern plate,
And a sand filling nozzle formed in a member detachably mounted on an opening of a side portion of the peeling frame, the sand filling nozzle communicating with the molding space. A mold-making machine for molding a mold by using a loaded flask and a pattern plate,
A filling frame having a lower opening communicable with an upper opening of the flask;
A filling frame disposed above the filling frame and having a lower opening connectable with an upper opening of the filling frame,
A squeeze head mechanism having a plurality of squeeze feet that can be raised and lowered with respect to the squeeze board,
A sand filling hopper having at least one sand filling port for filling a casting mold in a molding space formed by the flask, the filling frame, the filling frame, the squeeze head mechanism, and the pattern plate,
And a sand filling nozzle formed at a side of the filling frame to allow the sand filling port and the molding space to communicate with each other. The method according to claim 1 or 2,
A mold frame forming a part of the molding space and surrounding the outer periphery of the pattern plate and sliding up and down;
And a liner detachable from the inner side of the frame frame. The method of claim 3,
Wherein the liner has urethane rubber as a material of an upper end face and an inner side face thereof. The method of claim 4,
Wherein the urethane rubber has a heat-resistant temperature of 70 to 90 占 폚. The method of claim 4,
Wherein the urethane rubber has a heat-resistant temperature of 110 to 130 占 폚.

Images