CN210651689U - Forming die of navigation wind gap panel - Google Patents

Abstract

The utility model discloses a forming die of navigation wind gap panel, including swing joint's last module and lower module, the last module base bottom of going up the module is equipped with the last mould benevolence with the lower mould benevolence butt joint that is established on the lower die holder of lower module, the last mould benevolence upwards establishes the upper type groove of shaping wind gap panel main part and connection spindle, the protruding shaping of making a plurality of shaping wind gaps in the upper type groove, the protruding main terrace die benevolence of shaping wind gap panel main part and the side convex mould benevolence of shaping connection spindle portion of making of lower mould benevolence, still concave the lower type groove that matches with the shaping in number and position on the main terrace die benevolence, when going up module and lower module butt joint, can make the butt joint of upper type groove and main terrace die benevolence and side convex mould benevolence and make shaping convex and lower type groove butt joint and form the die cavity of shaping; and the base of the lower die set is also provided with a material ejecting component, an ejector pin of the material ejecting component can penetrate through the lower die core and extend into the die cavity, and a navigation air port panel formed in the die cavity is ejected out and stripped when the forming die is demoulded.

Description

Forming die of navigation wind gap panel

Technical Field

The utility model belongs to the technical field of the vapour turning mold utensil technique and specifically relates to a forming die of navigation wind gap panel.

Background

An injection mold is a tool for producing plastic products and also a tool for giving the plastic products complete structure and precise dimensions. Injection molding is a process used to mass produce parts of some complex shapes. Specifically, the plastic melted by heating is injected into a mold cavity from an injection molding machine at high pressure, and a formed product is obtained after cooling and solidification.

The injection mold generally includes an upper mold, a lower mold, an upper mold core disposed on the upper mold, a lower mold core disposed on the lower mold core, and a matched mold closing/releasing operation between the upper mold core and the lower mold core is performed to complete the injection molding.

In the field of automobile products, parts of automobiles, such as a navigation air port panel, an instrument panel shell and the like, are also often injection molded through an injection mold. In the prior art, a navigation air port panel 001 shown in the attached drawing 1 is processed and produced in an integrated injection molding mode, so that the integrity and the attractiveness of the navigation air port panel are guaranteed, and meanwhile, a matching air port and a buckling ingot are formed. In the prior art, the injection mold for injection molding of the navigation air port panel has the defects of complex design, poor molding effect, inconvenience in mounting of the molded panel and assembling of the air grid, low production efficiency and great material waste.

Therefore, the market needs a mold for forming the navigation tuyere panel, which has a simple structure and high production efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a technical problem who solves is to the defect of the existence among the above-mentioned prior art, provides a forming die of navigation wind gap panel, and this mould structure is accurate, fashioned navigation wind gap panel appearance is graceful, and production efficiency is high.

In order to solve the technical problem, the technical scheme adopted by the utility model is that the forming die for the navigation tuyere panel comprises an upper die set and a lower die set which are movably connected through a guide pillar matched with a guide sleeve, the bottom end of an upper die base of the upper die set is provided with an upper die core which is movably butted with a lower die core arranged on a lower die base of the lower die set, the upper die core is upwards concaved into an upper groove of a forming tuyere panel main body and a connecting ingot part, a plurality of forming bulges of the forming tuyere are formed in the upper groove in a protruding manner, a main male die core of the forming tuyere panel main body and a side convex die core of the forming connecting ingot part are formed in the upper die core in a protruding manner, a lower groove matched with the forming bulges in number and position is further formed in the main male die core in a recessed manner, when the upper die set is butted with the lower die set, the upper groove can be butted with the main male die core and the side convex die core, the cavity is communicated with a pouring system of the forming mold; and the base of the lower die set is also provided with a material ejecting component, an ejector pin of the material ejecting component can penetrate through the lower die core and extend into the die cavity, and a navigation air port panel formed in the die cavity is ejected out and stripped when the forming die is demoulded.

As a further elaboration of the above technical solution:

in the above technical scheme, the upper die set further comprises a partition plate arranged on the upper die base and a top die base arranged on the partition plate, and the upper die base, the partition plate and the top die base are connected through a pin shaft vertically extending downwards from the top end of the top die base.

In the technical scheme, the upper die core is locked in an embedding groove formed in the bottom end of the upper die base through the first bolt matched with the side insert.

In the technical scheme, the lower die set further comprises a base and square iron, the square iron is arranged at two transverse ends of the base, the lower die holder is fixedly arranged on the square iron, the ejection assembly is arranged between the square iron, and the base, the square iron and the lower die holder are connected through bolts.

In the technical scheme, the lower die base is provided with an accommodating space, and the lower die core is embedded in the accommodating space and fixedly connected with the bottom insert through a second bolt in a locking manner.

In the above technical scheme, the guide pillars are respectively arranged at four corners of the top die holder, the guide sleeves are respectively arranged at four corners of the upper die holder and the lower die holder, each guide pillar vertically and downwardly sequentially penetrates through the guide sleeves arranged on the upper die holder and the lower die holder and penetrates through the square iron, and the upper die set and the lower die set are movably connected and matched with each other to be matched with the forming die or to be de-molded.

In the technical scheme, four positioning columns which extend vertically are further arranged at the positions, close to the guide columns or the guide sleeves, of the four corners of the lower die base, and positioning holes are formed in the positions, matched with the positioning columns, of the upper die base; and the positioning column is implanted into the matched positioning hole to match with the mold for positioning and mold assembly.

In the technical scheme, the ejection assembly further comprises a plurality of rows of guide columns fixedly arranged on the base, a bottom needle plate and an ejector plate are movably arranged on the guide columns, and the bottom needle plate and the ejector plate can vertically slide along the guide columns and are matched to drive the ejector pins arranged on the bottom needle plate and penetrating through the ejector plate to vertically move; still establish the installation guide arm on the base, the installation guide arm certainly vertical run through in base bottom behind end faller and the thimble board with the die holder is connected, each install on the guide arm the cover is equipped with reset spring between end faller and the die holder, reset spring is used for providing damping transmission end faller moves the thimble and moves the position after ejecting the stripping with navigation wind gap panel.

In the technical scheme, a plurality of first guide rods which extend vertically and movably penetrate through the bottom needle plate and the ejector plate are further arranged on the base, first shaft sleeves are further arranged at the positions, matched with the first guide rods, of the bottom needle plate and the ejector plate, and the first guide rods are matched with the first shaft sleeves to enable the bottom needle plate and the ejector plate to vertically slide along the first guide rods in a matching manner; the ejector plate is also provided with a plurality of second guide rods, the second guide rods vertically penetrate through the ejector plate upwards from the bottom end of the ejector plate and penetrate through the lower die holder to be movably connected with the lower die holder, and the ejector pins are driven by the ejector plate to stably and vertically move in a matching mode; the base is provided with a plurality of garbage nails which are used for supporting the bottom needle plate to form an interval space.

In the technical scheme, the ejector pins comprise round ejector pins movably embedded in a main male die core and a side male die core, square ejector pins embedded in one side edge of the main male die core in the width direction, insert ejector pins embedded in the main male die core and flat ejector pins embedded in two sides of the main male die core in the length direction; the round ejector pins, the square ejector pins, the insert ejector pins and the flat ejector pins vertically extend upwards into the cavity and are matched with the mold for demolding, and the navigation air port panel formed in the cavity is ejected out.

Compared with the prior art, the utility model has the advantages that the mould of the utility model is used for processing the navigation tuyere panel, and the navigation tuyere panel formed by the mould has smooth plane and beautiful appearance; meanwhile, the production efficiency of the die is high, and the material waste is less; furthermore, the utility model discloses a mould structure is retrencied, long service life.

Drawings

FIG. 1 is the schematic view of the navigation tuyere panel of the mold forming of the utility model

Fig. 2 is a schematic perspective view of the mold of the present invention;

fig. 3 is an exploded view of the mold of the present invention;

fig. 4 is an assembly view of the lower die set of the die of the present invention;

FIG. 5 is an assembly view of the lower die holder and the lower die core of the present invention;

fig. 6 is an assembly view of the base and the ejector assembly of the mold of the present invention;

fig. 7 is an assembly view of the upper die base, the partition plate, the top die base and the upper die of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The embodiments described by referring to the drawings are exemplary and intended to be used for explaining the present application and are not to be construed as limiting the present application. In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and thus should not be considered limiting. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise. In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral connections; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate. In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact of the first and second features, or may comprise contact of the first and second features not directly but through another feature in between. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly above and obliquely above the second feature, or merely means that the first feature is at a lesser level than the second feature

Fig. 1-7 illustrate an embodiment of the present invention, which is a forming mold for a navigation tuyere panel, comprising an upper mold unit 300 and a lower mold unit 400 movably connected by a guide post 100 in cooperation with a guide sleeve 200, wherein an upper mold core 32 movably butted with a lower mold core 42 disposed on a lower mold base 41 of the lower mold unit 400 is disposed at the bottom end of an upper mold base 31 of the upper mold unit 300, the upper mold core 32 is upwardly and inwardly recessed to form a tuyere panel main body 002 and an upper groove 321 for connecting a spindle 003, a plurality of forming protrusions 322 for forming a tuyere 004 are formed in the upper groove 321, a main mold core 421 for forming a tuyere panel main body 002 and a side protrusion mold core 422 for forming a connecting spindle 003 are formed on the lower mold core 42, a lower mold core 423 matched with the forming protrusions 322 in number and position is further recessed on the main mold core 421, in this embodiment, three tuyeres 004 are disposed on the navigation tuyere panel 001, the number of the forming protrusions 322 and the number of the lower mold grooves 423 are correspondingly three, when the upper mold set 300 and the lower mold set 400 are butted, the upper mold groove 321 can be butted with the main male mold core 421 and the side male mold core 422, the forming protrusions 322 can be butted with the lower mold grooves 423 to form a mold cavity for forming the navigation air inlet panel 001, and the mold cavity is communicated with the casting system 800 of the forming mold; the base 43 of the lower die set 400 is further provided with a material ejecting assembly 500, and an ejector pin 51 of the material ejecting assembly 500 can penetrate through the lower die core 42 and extend into the die cavity, and ejects and removes the navigation air port panel 001 formed in the die cavity when the forming die is demoulded.

In this embodiment, referring to fig. 1 to 7, the upper die set 300 further includes a partition 33 disposed on the upper die holder 31 and a top die holder 34 disposed on the partition 33, and the upper die holder 31, the partition 33 and the top die holder 34 are connected by a pin 35 extending vertically downward from the top end of the top die holder 34 through the partition 33 and through the upper die holder 31; in this embodiment, the upper die core 32 is locked in an insert slot 311 formed at the bottom end of the upper die holder 31 by a first bolt 36 and a side insert 37.

In this embodiment, referring to fig. 1 to 7, the lower die set 400 further includes a base 43 and square irons 44, the square irons 44 are disposed at two lateral ends of the base 43, the lower die base 41 is fixedly disposed on the square irons 44, the material ejecting assembly 500 is disposed between the square irons 44, and the base 43, the square irons 44 and the lower die base 41 are connected by bolts 45; in this embodiment, the lower die holder 41 is provided with a receiving space 411, and the lower die core 42 is embedded in the receiving space 411 and is fixedly locked to the bottom insert 46 by a second bolt (not numbered in the drawings).

In this embodiment, the four corners of the top die holder 34 are provided with the guide pillars 100, the four corners of the upper die holder 31 and the lower die holder 41 are provided with the guide sleeves 200 (in the drawing, the guide sleeves 200 on the lower die holder 41 are not assembled), each guide pillar 100 vertically and downwardly penetrates the guide sleeves 200 on the upper die holder 31 and the lower die holder 41 in sequence and penetrates the square iron 44, and the upper die set 300 and the lower die set 400 are movably connected and matched with the forming die for closing or demolding; in this embodiment, four positioning pillars 600 extending vertically are further disposed at four corners of the lower die holder 41 near the guide pillars 100 or the guide sleeves 200, and positioning holes 312 are disposed at positions on the upper die holder 31 matching with the positioning pillars 600; the positioning column 600 is implanted into the matched positioning hole 312 to match the mold for positioning and mold assembly.

In this embodiment, referring to fig. 1 to 7, the ejector assembly 500 further includes a plurality of rows of guiding columns 52 fixed on the base 43, a bottom needle plate 53 and an ejector plate 54 are movably installed on the guiding columns 52, and the bottom needle plate 53 and the ejector plate 54 can slide vertically along the guiding columns 52 to drive the ejector 51 installed on the bottom needle plate 53 and penetrating through the ejector plate 54 to move vertically; the base 43 is further provided with mounting guide rods 55, the mounting guide rods 55 vertically penetrate through the bottom pin plate 53 and the ejector plate 54 from the bottom end of the base 43 and then are connected with the lower die holder 41, a return spring 56 is sleeved between the bottom pin plate 53 and the lower die holder 41 on each mounting guide rod 55, and the return spring 56 is used for providing damping transmission to the bottom pin plate 53 to drive the ejector pins 51 to eject and strip the navigation air port panel 001 and then retreat; in this embodiment, the base 43 is further provided with a plurality of first guide rods 57 which extend vertically and movably penetrate through the bottom pin plate 53 and the ejector pin plate 54, the penetrating positions of the bottom pin plate 53 and the ejector pin plate 54, which are matched with the first guide rods 57, are further provided with first bushings 58, and the first guide rods 57 are matched with the first bushings 58 to enable the bottom pin plate 53 and the ejector pin plate 54 to slide vertically along the first guide rods 57; the ejector plate 54 is also provided with a plurality of second guide rods 59, the second guide rods 59 vertically penetrate through the ejector plate 54 from the bottom end of the ejector plate 54 upwards and penetrate to the lower die holder 41 to be movably connected with the lower die holder 41, and the ejector plate 54 is matched to drive the ejector pins 51 to stably and vertically move; the base 43 is provided with a plurality of garbage nails 700, the garbage nails 700 are used for supporting the bottom needle plate 53 to form an interval space, the upper end surfaces of the garbage nails 700 are planes, and the upper end surfaces of all the garbage nails 700 are positioned on the same horizontal plane, so that when the thimble 51 is reset, the bottom needle plate 53 is only in contact with the garbage nails 700 in an attaching manner, the attaching surface is reduced, impurities are left in the space supported by the garbage nails 700, and the problem of uneven attaching is avoided; in this embodiment, the thimble 51 includes a round thimble 511 movably embedded in the main convex mold core 421 and the side convex mold core 422, a square thimble 512 embedded in one side of the main convex mold core 421 in the width direction, an insert thimble 513 embedded in the main convex mold core 421, and flat thimbles 514 embedded in both sides of the main convex mold core 421 in the length direction; the round ejector pins 511, the square ejector pins 512, the insert ejector pins 513 and the flat ejector pins 514 vertically extend upwards into the cavity and are matched with the mold for demolding, and the navigation air port panel 001 formed in the cavity is ejected out.

The technical scope of the present invention is not limited to the above embodiments, and any modifications, equivalent changes and modifications made to the above embodiments according to the technical spirit of the present invention are still within the scope of the technical solution of the present invention.

Claims (10)

1. A forming die for a navigation air port panel is characterized by comprising an upper die set and a lower die set which are movably connected through a guide post matched with a guide sleeve, the bottom end of the upper die base of the upper die set is provided with an upper die core which is movably butted with a lower die core arranged on a lower die base of the lower die set, the upper die core is upwards and inwards concave to form an air port panel main body and an upper groove connecting the spindle part, a plurality of forming protrusions for forming air ports are convexly arranged in the upper groove, the lower die core is convexly provided with a main convex die core for forming the tuyere panel main body and a side convex die core for forming the connecting ingot part, the main convex die core is also concavely provided with lower grooves matched with the forming protrusions in number and position, when the upper module and the lower module are assembled, the upper type groove can be butted with the main male die core and the side convex die core, the forming protrusion can be butted with the lower type groove to form a cavity for forming the navigation air port panel, and the cavity is communicated with a pouring system of a forming die; and the base of the lower die set is also provided with a material ejecting component, an ejector pin of the material ejecting component can penetrate through the lower die core and extend into the die cavity, and a navigation air port panel formed in the die cavity is ejected out and stripped when the forming die is demoulded.

2. The forming die for the navigation air inlet panel according to claim 1, wherein the upper die set further comprises a partition plate arranged on the upper die set and a top die set arranged on the partition plate, and the upper die set, the partition plate and the top die set are connected through a pin shaft vertically extending downwards from the top end of the top die set.

3. The forming die for the navigation tuyere panel of claim 2, wherein the upper die core is locked in an embedding groove formed at the bottom end of the upper die base by a first bolt-fitting side insert.

4. The forming die for the navigation tuyere panel as claimed in claim 2, wherein the lower die set further comprises a base and square irons, the square irons are arranged at two transverse ends of the base, the lower die base is fixedly arranged on the square irons, the ejection assembly is arranged between the square irons, and the base, the square irons and the lower die base are connected through bolts.

5. The forming die for the navigation tuyere panel as claimed in claim 4, wherein an accommodating space is formed on the lower die holder, and the lower die core is embedded in the accommodating space and is fixedly locked to the bottom insert through a second bolt.

6. The forming mold for a navigation tuyere panel according to claim 4, wherein the guide posts are disposed at four corners of the top mold base, the guide sleeves are disposed at four corners of the upper mold base and the lower mold base, each guide post penetrates the guide sleeves disposed on the upper mold base and the lower mold base vertically and sequentially downwards and penetrates the square iron, and the upper mold base and the lower mold base are movably connected and the forming mold is closed or released from the forming mold by matching.

7. The forming die for the navigation air port panel according to any one of claims 1 to 6, wherein four positioning columns extending vertically are further arranged at the positions, close to the guide columns or the guide sleeves, of four corners of the lower die holder, and positioning holes are formed in the positions, matched with the positioning columns, of the upper die holder; and the positioning column is implanted into the matched positioning hole to match with the mold for positioning and mold assembly.

8. The mold for forming a navigation tuyere panel according to claim 7, wherein the ejector assembly further comprises a plurality of rows of guide posts fixed on the base, a bottom needle plate and an ejector plate are movably mounted on the guide posts, and the bottom needle plate and the ejector plate can slide vertically along the guide posts and are matched to drive the ejector pins mounted on the bottom needle plate and penetrating through the ejector plate to move vertically; still establish the installation guide arm on the base, the installation guide arm certainly vertical run through in base bottom behind end faller and the thimble board with the die holder is connected, each install on the guide arm the cover is equipped with reset spring between end faller and the die holder, reset spring is used for providing damping transmission end faller moves the thimble and moves the position after ejecting the stripping with navigation wind gap panel.

9. The forming die for the navigation air port panel according to claim 8, wherein a plurality of first guide rods which extend vertically and movably penetrate through the bottom needle plate and the ejector plate are further arranged on the base, first bushings are further arranged on the bottom needle plate and the ejector plate at positions which are matched with the first guide rods and penetrate through the first bushings, and the first guide rods are matched with the first bushings to enable the bottom needle plate and the ejector plate to slide vertically along the first guide rods; the ejector plate is also provided with a plurality of second guide rods, the second guide rods vertically penetrate through the ejector plate upwards from the bottom end of the ejector plate and penetrate through the lower die holder to be movably connected with the lower die holder, and the ejector pins are driven by the ejector plate to stably and vertically move in a matching mode; the base is provided with a plurality of garbage nails which are used for supporting the bottom needle plate to form an interval space.

10. The forming die for the navigation tuyere panel according to claim 9, wherein the ejector pins comprise round ejector pins movably embedded in the main core and the side core, square ejector pins embedded in one side edge of the main core in the width direction, insert ejector pins embedded in the main core, and flat ejector pins embedded in both sides of the main core in the length direction; the round ejector pins, the square ejector pins, the insert ejector pins and the flat ejector pins vertically extend upwards into the cavity and are matched with the mold for demolding, and the navigation air port panel formed in the cavity is ejected out.

Images