阅读说明：本技术 多向开模成型结构 (Multidirectional die sinking forming structure ) 是由 田跃文 朱立群 张显东 姜鲁 夏恩帅 张峰 于 2020-07-09 设计创作，主要内容包括：本发明多向开模成型结构,包括对应设置的上模和下膜,上模和下模分别包括与产品的上侧及下侧形状对应的上仿形腔及下仿形腔,上仿形腔对应设置有与圆孔组匹配的上模芯；上模和下模间还设置有与产品的左侧、右侧、前侧、及后侧形状匹配的左侧开模组件、右侧开模组件、前侧开模组件、以及后侧开模组件；左侧开模组件包括左侧开模驱动件、连接于左侧开模驱动件的左侧模芯,左侧模芯端部为与左凹槽匹配的左侧仿形体,且左侧模芯上设置有用于金属液流入的浇道口组件。(The invention discloses a multidirectional die-sinking forming structure, which comprises an upper die and a lower die which are correspondingly arranged, wherein the upper die and the lower die respectively comprise an upper profiling cavity and a lower profiling cavity which correspond to the shapes of the upper side and the lower side of a product, and the upper profiling cavity is correspondingly provided with an upper die core matched with a round hole group; a left die opening assembly, a right die opening assembly, a front die opening assembly and a rear die opening assembly which are matched with the left side, the right side, the front side and the rear side of the product in shape are also arranged between the upper die and the lower die; the left side die sinking subassembly includes left side die sinking driving piece, connects in the left side mold core of left side die sinking driving piece, and left side mold core tip is the left side imitative physique that matches with left recess, and is provided with the mouth subassembly of watering that is used for the molten metal to flow in on the mold core of left side.)

1. The utility model provides a multidirectional die sinking forming structure which characterized in that: the die comprises an upper die and a lower die which are arranged correspondingly, wherein the upper die and the lower die respectively comprise an upper profiling cavity and a lower profiling cavity which correspond to the upper side and the lower side of a product in shape, and the upper profiling cavity is correspondingly provided with an upper die core matched with the circular hole group; a left die opening assembly, a right die opening assembly, a front die opening assembly and a rear die opening assembly which are matched with the left side, the right side, the front side and the rear side of the product in shape are also arranged between the upper die and the lower die; the left side die sinking subassembly includes left side die sinking driving piece, connects in the left side mold core of left side die sinking driving piece, and left side mold core tip is the left side imitative physique that matches with left recess, and is provided with the mouth subassembly of watering that is used for the molten metal to flow in on the mold core of left side.

2. The multi-directional mold-opening molding structure according to claim 1, wherein: the right die sinking component comprises a right die body setting frame, a right slide rail arranged on the right die body setting frame and a right die core arranged on the right slide rail in a sliding manner; the end part of the right mold core is a right profile modeling body matched with the right groove.

3. The multi-directional mold-opening molding structure according to claim 2, wherein: the right side slide and the right side mold core are correspondingly provided with right oblique fixing holes, and the right oblique fixing holes are fixedly formed by arranging right fixing columns in the right oblique fixing holes.

4. The multi-directional mold-opening molding structure according to claim 3, wherein: the front side die opening assembly comprises a front side die body setting frame, a front side die opening driving part obliquely arranged on the front side die body setting frame, and a front die core connected to the front side die opening driving part and an oblique hole.

5. The multi-directional mold-opening molding structure according to claim 4, wherein: the slant mold core includes the slant slider that slides the setting, connects in the slant of slant slider and the slant cylinder that the slant hole matches.

6. The multi-directional mold-opening molding structure according to claim 5, wherein: the left side die opening driving part and the front side die opening driving part are both formed by cylinders.

7. The multi-directional mold-opening molding structure according to claim 6, wherein: the rear side die opening assembly comprises a rear side die body arranging frame, a rear side sliding channel arranged on the rear side die body arranging frame and a rear side die core arranged on the rear side sliding channel in a sliding manner; the end part of the back die core is a back profile body matched with the back groove.

8. The multi-directional mold-opening molding structure according to claim 7, wherein: rear oblique fixing holes are correspondingly formed in the rear side slideway and the rear side mold core, and rear fixing columns are arranged in the rear oblique fixing holes to form fixation.

Technical Field

The invention relates to a molding technology, in particular to preparation of automobile parts, and particularly discloses a multidirectional die-sinking molding structure.

Background

Die casting is called casting for short, and is a precision forming technology for metal parts close to the final shape and size, and the final product is a die casting. The essence of the method is that under the action of high pressure, liquid metal is filled into a die cavity at high speed, and is formed and solidified under the action of pressure, so that a die casting with clear outline and smooth surface is obtained. In the non-ferrous metal casting industry, die casting is an important casting method. In recent years, light alloys mainly containing magnesium and aluminum have gained importance in the die casting industry, and aluminum alloy castings obtained by die casting account for about six components of the total amount of lead alloy castings.

The die-casting forming of partial products at the present stage has a need for improvement, for example, a product 100 shown in fig. 1-2 includes a product main body 101, the upper side of the product main body is provided with a circular hole group 102, the lower side is provided with an inner groove 103, the left side is provided with a left groove 104, the right side is provided with a right groove 105, the front side is provided with an inclined hole 106, the rear side is provided with a rear groove 107, three-dimensional six surfaces of the product all have concave characteristics, the product is easily damaged by the forming method at the present stage, and meanwhile, a plurality of characteristics need to be processed after forming, so that the product quality.

Therefore, it is necessary to provide a multi-directional mold-opening forming structure to solve the above problems.

Disclosure of Invention

The invention aims to provide a multidirectional die-sinking forming structure, which ensures that the characteristics contained in each side of a product can be well formed by setting a multi-side die-sinking structure corresponding to the product.

The technical scheme is as follows:

a multidirectional die sinking forming structure comprises an upper die and a lower die which are arranged correspondingly, wherein the upper die and the lower die respectively comprise an upper profiling cavity and a lower profiling cavity which correspond to the shapes of the upper side and the lower side of a product, and the upper profiling cavity is correspondingly provided with an upper die core matched with a round hole group; a left die opening assembly, a right die opening assembly, a front die opening assembly and a rear die opening assembly which are matched with the left side, the right side, the front side and the rear side of the product in shape are also arranged between the upper die and the lower die; the left side die sinking subassembly includes left side die sinking driving piece, connects in the left side mold core of left side die sinking driving piece, and left side mold core tip is the left side imitative physique that matches with left recess, and is provided with the mouth subassembly of watering that is used for the molten metal to flow in on the mold core of left side.

Further, the right side die sinking assembly comprises a right side die body setting frame, a right side slideway arranged on the right side die body setting frame, and a right side die core arranged on the right side slideway in a sliding manner; the end part of the right mold core is a right profile modeling body matched with the right groove.

Furthermore, a right inclined fixing hole is correspondingly formed in the right side slideway and the right side mold core, and the right fixing column is arranged in the right inclined fixing hole to form fixing.

Furthermore, the front side die opening assembly comprises a front side die body setting frame, a front side die opening driving part obliquely arranged on the front side die body setting frame, and a front die core connected to the front side die opening driving part and an oblique hole.

Furthermore, the slant mold core includes the slant slider that slides the setting, connects in the slant of slant slider and the slant cylinder that the slant hole matches.

Furthermore, the left side die opening driving part and the front side die opening driving part are both formed by cylinders.

Further, the rear side die opening assembly comprises a rear side die body arranging frame, a rear side sliding channel arranged on the rear side die body arranging frame, and a rear side die core arranged on the rear side sliding channel in a sliding manner; the end part of the back die core is a back profile body matched with the back groove.

Furthermore, rear inclined fixing holes are correspondingly formed in the rear side sliding channel and the rear side mold core, and rear fixing columns are arranged in the rear inclined fixing holes to form fixing.

Compared with the prior art, the multi-surface die sinking structure is set corresponding to the product, so that the characteristics contained in each surface of the product can be well formed.

Drawings

Fig. 1 is one of the schematic structural views of product 100.

Fig. 2 is a second schematic structural diagram of the product 100.

Fig. 3 is one of the structural schematic diagrams of the present invention.

FIG. 4 is a second schematic structural diagram of the present invention.

Fig. 5 is a third schematic structural diagram of the present invention.

FIG. 6 is a fourth schematic view of the present invention.

FIG. 7 is a fourth schematic view of the present invention.

FIG. 8 is a fourth schematic view of the present invention.

Detailed Description