CN112247074A - Core clamping and pressing method and clamping and pressing device thereof - Google Patents

Abstract

The core clamping and pressing device fixes a core at a determined position through a pressing part, so that the core which is formed by assembly cannot displace or cause metal liquid overflow, fire running and the like due to the expansive force of the metal liquid in the casting process, good mold filling and condensation of the metal liquid in a cavity of the core are ensured, and the naked casting of a casting is realized. Through the implementation of the technical scheme, two processes of manufacturing a sand box and embedding the sand box are omitted in the casting process of the casting, so that the process flow of casting production is shortened, the corresponding manufacturing cost and time are saved, and the production efficiency is improved.

Description

Core clamping and pressing method and clamping and pressing device thereof

Technical Field

The invention relates to a clamping and pressing device for casting, in particular to a clamping and pressing method and a clamping and pressing device for a core bag in a bare casting process.

Background

Casting is a method in which liquid metal is cast into a casting cavity that conforms to the shape of a part, and after it is cooled and solidified, a part or a blank is obtained. In the existing production process, after the manufactured sand core and sand mold or modeling are subjected to core assembly, a sand box is sleeved on the periphery, the sand is filled in the sand box and is compacted, and then the sand box is compacted at the upper part and then is cast. The sand box or the sand box frame required by products with different specifications is specially manufactured in the process, so that the operation not only prolongs the production efficiency, but also increases the manufacturing cost of each product, and the castings are mostly produced in a single piece mode, so that the waste is more likely to occur. In order to avoid the process delay and cost increase caused by manufacturing the sand core, the currently adopted technology is the box-free casting, namely the naked casting. However, at present, the weight of products produced by bare casting is smaller, generally less than 100kg, and a small clamp, such as a screw four-corner clamp, needs to be matched. With the 3DP printing technology in the casting area, cores for medium castings have been printed indirectly, which saves the cost of sand cores and sand molds, but still requires core-embedding boxes after core assembly, and sand boxes to provide the core package with forces that counter the hydraulic expansion forces.

Disclosure of Invention

In view of the problems of large sand-iron ratio, long manufacturing period and high production cost caused by adopting the sand box to fasten the core, a core clamping and pressing method and a clamping and pressing device thereof are needed, and the core clamping and pressing device replaces the fastening effect of the sand box on the core and realizes the bare casting of the casting.

A core clamping and pressing method is characterized in that a core is fixed at a determined position through a pressing part, so that the assembled and molded core cannot be displaced or cause overflow, fire escape and the like of molten metal due to the expansion force of the molten metal in the casting process, good mold filling and condensation of the molten metal in a cavity of the core are guaranteed, and the casting is cast in a naked mode. For example, the pressing portion may be a mechanical structure having a pressing function, such as a mechanical press handle, and the upper end surface and/or the four side walls of the core are pressed and/or tightened by the pressing portion, so that the components of the core are in a certain position, and cannot be displaced relatively and cannot exceed a set contour range of the core.

More specifically, the clamping and/or pressing force of the pressing part on the core is only used for maintaining the core in a certain position without applying extra pressure on the core, or the purpose of the pressing part is to make the core ring stay in the range of the outer contour of the core, or the terminal position of the pressing part stays on the outer contour surface of the core, and the pressing part has certain maintaining force to prevent the terminal of the pressing part from shaking, shifting and the like caused by the expansion force of molten metal, namely the clamping or pressing force is equal to the expansion force of the molten metal on the core in the processes of filling and condensing.

Specifically, the pressing part is provided with a vertical pressing hand and/or a transverse pressing hand. The vertical pressing hand acts on the upper end face of the core, and the vertical pressing hand replaces the existing pressing iron, locking screw rods and the like to provide downward pressing force for the core, so that the core is prevented from being lifted in the molten metal filling and condensing processes, and fire running or overlarge casting size deviation caused by the fact that the core is lifted is avoided. The transverse pressing hands act on the four side walls of the core, and the transverse pressing hands provide horizontal tightening force perpendicular to the side walls, so that the core is prevented from outwards shifting in the molten metal filling and condensing processes, and the problems that the size deviation of a casting caused by shifting of all blocks of the core exceeds the standard, a flash is too large and the like are solved.

The technical effect of the technical scheme is as follows: through the implementation of the technical scheme, two processes of manufacturing a sand box and embedding the sand box are omitted in the casting process of the casting, so that the process flow of casting production is shortened, the corresponding manufacturing cost and time are saved, and the production efficiency is improved.

Drawings

FIG. 1 is a schematic view of a core chucking apparatus;

FIG. 2 is a schematic view of a lateral press hand;

in the figure, 100-frame; 101-a column; 102-a beam; 103-vertical guide rails; 200-an actuator; 300-pressing the hand transversely; 301-a pallet; 302-a compression member; 303-a third drive member; 304-expanding the plate; 400-a drive section; 401-driving the slider; 402-a drive member; 403-transmission piece.

Detailed Description

In order to more clearly illustrate the technical solution of the present invention, the detailed description will be given according to the embodiments of the drawings, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

In order to put the core chucking method of the present invention into practical use in production, a core chucking apparatus as described below is now designed according to the core chucking method.

The first embodiment is as follows:

this embodiment still adopts modes such as current swage iron, locking screw to realize compressing tightly the vertical direction of core based on the core, and the new increase is to the horizontal tightening force of core to avoid the displacement of core on the horizontal direction.

A core clamping and pressing device is provided with a transverse pressing hand 300, wherein the transverse pressing hand 300 comprises a saddle 301, a pressing piece 302 and a third driving piece 303; the support table 301 is used for supporting the mold core to be clamped and pressed, a protrusion is arranged on the edge of the support table 301, and the protrusion extends in the vertical upward direction away from the support table 301; the end, far away from the saddle 301, of the protrusion is provided with the pressing piece 302, and the pressing piece 302 is sleeved on the protrusion in a penetrating manner, that is, one end of the pressing piece 302 is located on the inner side of the saddle 301, and the other end of the pressing piece 302 is located on the outer side of the saddle 301; the third driving element 303 is arranged at the end of the pressing element 302 positioned outside the pallet 301, and the third driving element 303 can make the pressing element 302 advance and retreat along the direction parallel to the pallet 301 and can lock the pressing element 302 at any position of parking. In this embodiment, the pallet 301 is a rectangular parallelepiped with four protrusions on the edge of the upper end surface and support legs on the lower end surface, the protrusions are plate-shaped protrusions with a certain thickness extending along the edges of the four side walls of the rectangular parallelepiped in the vertical upward direction, and the support legs may be fixed support legs or movable wheel-type support legs with a self-locking function; the cylindrical pressing piece 302 is arranged in the direction of the protrusion far away from the cuboid plane of the saddle 301, the cylindrical pressing piece 302 is connected to the protrusion in a penetrating mode and can reciprocate in the horizontal direction along the protrusion, namely the length of one end, located on the inner side of the saddle 301, of the pressing piece 302 can be adjusted, and therefore the clamping effect on the side wall of the mold core is achieved; in order to conveniently realize the effect of the pressing piece 302, the third driving piece 303 is arranged at the end of the pressing piece 302 positioned outside the supporting platform 301, the third driving piece 303 is a turbine type rocking handle with a self-locking function, and the pressing piece 302 can be moved in and out by rotating the turbine type rocking handle, namely, the clamping of the side wall of the core is realized.

Preferably, an expansion plate 304 is arranged at the end of the pressing piece 302 positioned inside the saddle 301, and the expansion plate 304 can increase the contact area between the pressing piece 302 and the core side wall, so that the clamping force applied to the core side wall by the pressing piece 302 is improved, the clamping force can be more uniformly applied to the core side wall, and the damage to the core side wall possibly caused by the small contact area and the large applied clamping force of the pressing piece 302 is avoided.

Example two:

this embodiment adopts vertical pressure hand to replace modes such as current swage iron, locking screw, realizes compressing tightly the vertical direction of core to increase the horizontal cramping force to the core. The parts of the lateral pressing hand 300 already described in the first embodiment are not described again.

The core clamping and pressing device comprises a transverse pressing hand 300 and a vertical pressing hand, wherein the vertical pressing hand comprises a frame 100, an actuating piece 200 and a driving part 400, the driving part 400 is arranged on the frame 100, and the frame 100 is arranged on the ground, so that the stability of the core clamping and pressing device is ensured; the actuating member 200 is connected with the driving part 400, and the driving part 400 drives the actuating member 200 to reciprocate in the vertical direction, so that the vertical direction of the core is pressed; the transverse pressing hand 300 is a clamping and pressing support table, and a core needing clamping and pressing is placed on the clamping and pressing support table, and the solid mold clamps the core in the horizontal direction.

The frame 100 comprises upright columns 101, cross beams 102 and vertical guide rails 103, wherein the four upright columns 101 are fixedly arranged on the ground, the upright columns 101 are provided with the cross beams 102, the cross beams 102 are arranged on the upright columns 101 in two groups, one group of the cross beams is arranged at the tops of the upright columns 101 and is a top cross beam, the other group of the cross beams is arranged in the middle of the upright columns 101 and is a middle cross beam, and the vertical guide rails 103 are arranged between the top cross beam and the middle cross beam.

The driving part 400 comprises a driving slider 401, a driving element 402 and a transmission element 403, wherein the driving slider 401 is arranged on the vertical guide rail 103 and can slide up and down along the vertical guide rail 103; the driving part 402 is arranged at one end of the vertical guide rail 103 close to the top cross beam, that is, the driving part 402 is arranged at the top of the vertical guide rail 103, and specifically is arranged on a cross bar on the vertical guide rail 103, that is, a cross bar is arranged at the top of the vertical guide rail 103 (that is, at one end close to the top cross beam), the driving part 402 is arranged on the cross bar, and the driving part 402 is used for driving the driving slider 401 to slide up and down along the vertical guide rail 103, so that the executing part 200 can move up and down to be suitable for cores with different heights; the transmission piece 403 is arranged on the driving slider 401, that is, the driving slider 401 drives the transmission piece 403 to move up and down along the vertical guide rail 103, that is, one end of the transmission piece 403 is connected to one end of the driving slider 401 close to the top cross beam, and the transmission piece 403 can also move left and right along the driving slider 401 in the horizontal direction; the other end of the transmission member 403 is connected with the actuating member 200, so that the actuating member 200 can avoid the casting process location of the upper end surface of the core. For the embodiment, the driving part 402 is a motor with a screw rod on an output shaft, the motor is mounted on a transverse rod, the screw rod is vertically downward and parallel to the upright post 101, the driving slider 401 passes through the screw rod and is bridged on the vertical guide rail 103, and the driving slider 401 is driven by the screw rod to move up and down along the vertical guide rail 103; the transmission member 403 is of a right-angled triangle frame structure, a long right-angled side of the right-angled triangle frame is parallel to the vertical guide rail 103, and one end of the long right-angled side, which is far away from the short right-angled side, is fixedly connected to the driving slider 401, so that the transmission member 403 and the driving slider 401 move synchronously, and the short right-angled side is the tail end of the transmission member 403.

Preferably, two transmission elements 403 are symmetrically arranged on the drive slide 401, i.e. the transmission elements 403 are arranged in groups, so that the pressing force on the upper end face of the core is more uniform and balanced. The number of the actuating elements 200 corresponds to the number of the transmission elements 403, and each of the transmission elements 403 is provided with one of the actuating elements 200.

Preferably, a second driving member is further provided on the driving slider 401, and the second driving member is used for adjusting the distance between the two transmission members 403, so that the cores with different sizes can be adapted, and the position of each transmission member 403 can be relatively adjusted according to the setting of casting process locations such as a gate, a dead head and the like on the upper end surface of the core, that is, the distance between the two transmission members 403 is changed, and the final purpose is to change the pressing position of the actuating member 200 relative to the upper end surface of the core.

The actuating member 200 is attached to the end of the transmission member 403 to act on the upper end face of the core. The actuating member 200 is a rectangular parallelepiped strip-shaped structure horizontally disposed at the end of the driving member 403, so that the actuating member can contact with the upper end surface of the mold core in the largest area, and the best pressure-bearing effect can be obtained. In the present embodiment, two transmission members 403 are provided, and two actuating members 200 are also provided, and in the case that a casting process gate, a riser and the like are provided in the middle of the upper end surface of the core, the two actuating members 200 can be pressed on the upper end surface of the core by bypassing the casting process region such as the gate and the riser, so as to realize symmetrical and balanced pressure application on the core. More specifically, the actuating member 200 may be made of H-shaped steel.

The specific structure of the lateral pressing hand 300 is as described in the first embodiment.

As an optimization of this embodiment, depending on the width of the cross beam 102 or depending on the width/span of the frame 100, the vertical guide rails 103 may be provided with several groups side by side on the cross beam 102, for example, one group, two groups or three groups may be provided for the vertical guide rails 103, and in this embodiment, two groups are provided for the vertical guide rails 103. When the vertical guide rails 103 are provided with a plurality of groups, each group of the vertical guide rails 103 can be provided with one set of the driving part 400, so that one frame 100 can be provided with a plurality of sets of the driving part 400, the executing part 200 and the transverse press handle 300 which is configured according to different use objects, the purpose that a plurality of cores can be clamped and pressed on a station of one frame 100 is achieved, cores of various different types can be clamped and pressed on the same station is also achieved, production of various and single castings is met, and the production efficiency is improved while the utilization rate of unit area is improved.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (11)

1. A core clamping and pressing method is characterized in that a core is fixed at a determined position through a transverse pressing hand or/and a vertical pressing hand, so that the assembled and formed core cannot be displaced due to the expansion force of molten metal in the casting process.

2. The core chucking method as claimed in claim 1, wherein said lateral presser and/or vertical presser clamp said core by a clamping force and/or a pressing force applied to an upper end face and/or a wall of said core, and said pressing force or clamping force is equal to an expansion force of the molten metal.

3. The die core clamping and pressing device is characterized by comprising a transverse pressing hand, wherein the transverse pressing hand comprises a supporting platform, a pressing piece and a third driving piece; the support table is used for supporting the mold core needing clamping and pressing, and a bulge is arranged on the edge of the support table; the end, far away from the saddle, of the bulge is provided with the pressing piece, and the pressing piece is connected to the bulge in a penetrating manner; one end of the pressing piece, which is far away from the mold core, is provided with the third driving piece.

4. The core clamping and pressing device as claimed in claim 3, wherein an expansion plate is arranged on the end of the pressing piece positioned on the inner side of the saddle.

5. The core chucking apparatus of claim 3, wherein said third drive member is a turbine style rocking handle.

6. The core clamping and pressing device as claimed in any one of claims 3 to 5, further comprising a vertical pressing hand.

7. The core chucking apparatus of claim 6, wherein said vertical presser comprises a frame disposed on the ground, a driving portion disposed on said frame, and an actuator connected to said driving portion.

8. The core chucking apparatus of claim 7, wherein said frame includes columns, beams and vertical rails; four upright posts are arranged and are respectively arranged on the ground; the cross beam is bridged between the stand columns and is provided with a top cross beam and a middle cross beam; the vertical guide rail is disposed between the top cross member and the middle cross member.

9. The core chucking apparatus of claim 8, wherein said drive section includes a drive slide, a drive member, and a transmission member; the driving sliding block is arranged on the vertical guide rail and can slide along the vertical guide rail; the driving piece is arranged on a cross bar at the top of the vertical guide rail and used for driving the driving sliding block to slide along the vertical guide rail; the transmission part is arranged on the driving sliding block and moves up and down along with the sliding of the driving sliding block along the vertical guide rail.

10. The core chucking apparatus of claim 9, wherein there are two of said driving members symmetrically, and a second driving member is provided between said two driving members, said second driving member being for adjusting a relative distance between said two driving members.

11. The core chucking apparatus as recited in any of claims 7-10 wherein said drive portion is provided with a plurality of sets.

Images