CN112296615B

CN112296615B - O-shaped sealing ring die and machining process thereof

Info

Publication number: CN112296615B
Application number: CN202011091578.4A
Authority: CN
Inventors: 廖备铨
Original assignee: Xiamen Zhong Han Precision Industrial Co ltd
Current assignee: Xiamen Zhong Han Precision Industrial Co ltd
Priority date: 2020-10-13
Filing date: 2020-10-13
Publication date: 2023-03-31
Anticipated expiration: 2040-10-13
Also published as: CN112296615A

Abstract

The invention provides an O-shaped sealing ring mold which comprises a lower template and an upper template, wherein the lower template and the upper template are mutually matched to form at least one molding cavity for molding an O-shaped sealing ring, the molding cavity comprises an annular groove arranged on the upper end surface of the lower template and an annular bulge arranged on the lower end surface of the upper template and matched with the annular groove, and the annular bulge and the upper template are of an integrated structure; according to the O-shaped seal ring die, the integrated upper die plate and lower die plate are arranged, and the corresponding forming cutter and the forming process are matched, so that the processing period of the die can be shortened, and the production efficiency is improved.

Description

O-shaped sealing ring die and machining process thereof

Technical Field

The invention relates to the technical field of design and manufacture of silicon rubber molds, in particular to an O-shaped sealing ring mold and a processing technology thereof.

Background

With the development of technology, the application of the O-ring is more and more extensive, mainly using static seal and reciprocating motion seal, and using for rotary motion seal (only limited to low-speed rotary seal device). The O-shaped sealing ring mould has various types, but most of the O-shaped sealing ring moulds are provided with mould cores on an upper mould plate or a lower mould plate or both the upper mould plate and the lower mould plate, and then the upper mould plate and the lower mould plate are matched to form a cavity to process the O-shaped sealing ring.

The mold core adopting the disassembly and assembly type is arranged on the template, and has the following defects:

firstly, the assembly and disassembly type is adopted, so that the requirement on the installation precision is high, and the cost is increased;

secondly, the mold core needs to be arranged on the template, so that the production process of the O-shaped sealing ring mold is increased, and the efficiency is low;

thirdly, a gap may exist at the installation position of the mold core and the mold plate, and after long-time use, the gap is increased, so that burrs except the parting surface position exist in the O-shaped sealing ring.

In view of the above, the present invention provides an O-ring mold and a processing method thereof.

Disclosure of Invention

In order to solve the problems, the technical scheme of the invention is as follows:

in a first aspect, an object of the present invention is to provide an O-ring mold, which includes a lower template and an upper template, where the lower template and the upper template are matched with each other to form at least one molding cavity for molding an O-ring, the molding cavity includes an annular groove disposed on an upper end surface of the lower template and an annular protrusion disposed on a lower end surface of the upper template and matched with the annular groove, and the annular protrusion and the upper template are of an integrated structure.

Furthermore, a first overflow groove is formed in the lower template and located at the bottom of the annular groove.

Furthermore, a first chamfer is arranged at the opening of the first overflow groove, a second chamfer is arranged around the end face of the annular bulge close to the lower template, and the first chamfer and the second chamfer form a first channel.

Further, first chamfer and second chamfer parallel arrangement, the distance between the two is 10-50um.

Furthermore, a second overflow groove is formed in the end face, close to the lower template, of the upper template and located on the periphery of the annular protrusion.

Furthermore, a third chamfer is arranged at the opening of the annular groove, a fourth chamfer is arranged at the opening of the second overflow groove, and the third chamfer and the fourth chamfer form a second channel.

Further, the third chamfer and the fourth chamfer are arranged in parallel, and the distance between the third chamfer and the fourth chamfer is 10-50um.

Furthermore, the inner side wall of the annular groove is concave outwards, the bottom of the annular groove is concave downwards, the outer side wall of the annular protrusion is concave inwards, the joint of the outer side wall and the upper die plate is concave upwards, and the outer side wall and the upper die plate form a forming cavity of an O-shaped ring.

Furthermore, a plurality of molding cavities form a molding unit, guide grooves are formed in the periphery of the molding unit, and the guide grooves are formed in the upper end face of the lower template.

In a second aspect, a second object of the present invention is to provide a forming tool, configured to machine the annular groove and the annular protrusion in the first aspect, the forming tool includes a tool shank and a forming tool bit, the tool shank is connected to the forming tool bit through a transition portion, the forming tool bit is disposed at 135 degrees, a terminal of the forming tool bit is semicircular, and a specific center of the forming tool bit and a center of the tool shank are at 135 degrees.

In a third aspect, the invention provides a molding process of an O-ring mold, including molding an annular groove and molding an annular protrusion, where the annular groove is integrally formed on a lower mold plate and the annular protrusion is integrally formed on an upper mold plate, and where,

the annular groove forming comprises the following steps:

sa1, processing a circular groove: processing a circular groove by using a milling cutter;

sa2, processing inclined plane: boring the inner side wall of the circular groove by using a cutter with a 45-degree inclined surface, so that an opening of the inner side wall faces outwards to form an inclined surface, and a first overflow groove is formed at the bottom of the circular groove;

sa3, processing an annular groove: scraping the inclined surface by using a forming cutter of the second aspect, so that the upper part of the inclined surface is concave outwards and the lower part of the inclined surface is concave downwards to form an annular groove with a semicircular cross section;

the annular bulge forming comprises the following steps:

sb1, processing a circular boss, processing the circular boss by using a milling cutter, and forming a second overflow groove around the circular boss;

sb2, machining a conical table, boring the outer side wall of the circular boss by using a cutter with a 45-degree inclined plane, and forming the conical table on the outer side wall;

sb3, processing an annular bulge: and scraping the conical table by using the forming cutter of the second aspect, so that the upper part of the conical table is concave inwards and the lower part of the conical table is concave downwards to form an annular bulge with a semicircular cross section at two sides.

Further, when the annular groove is machined, the forming cutter scrapes clockwise; and when the annular boss is machined, the forming cutter scrapes anticlockwise.

According to the O-shaped seal ring die, the integrated upper die plate and lower die plate are arranged, and the corresponding forming cutter and the forming process are matched, so that the processing period of the die can be shortened, and the production efficiency is improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention and not to limit the invention.

Wherein:

FIG. 1 is a schematic structural view of a lower template of the present invention;

FIG. 2 is a schematic structural view of the upper die plate of the present invention;

FIG. 3 is a cross-sectional view of a single molding unit of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3 of the present invention;

FIG. 5 is an exploded view of FIG. 3 of the present invention;

FIG. 6 is an enlarged view of a portion of FIG. 5 of the present invention;

FIG. 7 is a schematic structural view of a forming tool according to the present invention (schematic view of a machining annular protrusion);

FIG. 8 is a schematic view of the forming tool machining an annular groove of the present invention;

FIG. 9 is a front view of a forming blade head of the forming knife of the present invention;

FIG. 10 is a side view of a forming head of the forming knife of the present invention;

FIG. 11 is a flow chart of the annular groove process of the present invention;

FIG. 12 is a flow chart of the process of the annular projection of the present invention.

Description of the reference symbols:

10. a lower template; 10a, a circular groove; 10b, a bevel; 11. an annular groove; 12. a first overflow tank; 13. a first chamfer; 14. a third chamfer; 15. a diversion trench; 20. mounting a template; 20a, a circular boss; 20b, a conical table; 21. an annular projection; 22. a second overflow tank; 23. a second chamfer; 24. a fourth chamfer; 30. forming a cavity; 40. a first channel; 50. a second channel; 60. forming a cutter; 61. a knife handle; 62. a transition section; 63. and (5) forming a cutter head.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects of the present invention more clear and obvious, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In a first aspect, please refer to fig. 1 to 6, which are provided by the present invention, the O-ring mold includes a lower mold plate 10 and an upper mold plate 20, the lower mold plate 10 and the upper mold plate 20 are assembled to form at least one molding cavity 30 for molding an O-ring, the molding cavity 30 includes an annular groove disposed on an upper end surface of the lower mold plate 10 and an annular protrusion 21 disposed on a lower end surface of the upper mold plate 20 and engaged with the annular groove, the annular protrusion 21 and the upper mold plate are of an integrated structure, that is, the molding cavity 30 corresponding to the upper mold plate 20 and the lower mold plate 10 can be formed by integral molding, and a parting surface is disposed at a 45-degree position corresponding to the O-ring, so as to avoid a sealing working surface of the O-ring, and greatly improve a sealing effect of the O-ring.

A first overflow groove 12 is formed in the lower die plate 10 and located at the bottom of the annular groove and used for storing redundant plastic, a first chamfer 13 is arranged at an opening of the first overflow groove 12, a second chamfer 23 is arranged on the periphery of the end face, close to the lower die plate 10, of the annular protrusion 21, the first chamfer 13 and the second chamfer 23 form a first channel 40, the first chamfer 13 and the second chamfer 23 are arranged in parallel, and the distance between the first chamfer 13 and the second chamfer 23 is 10-50 microns. A second overflow groove 22 is arranged on the end surface of the upper template close to the lower template 10 and around the annular bulge 21; a third chamfer 14 is arranged at the opening of the annular groove 11, a fourth chamfer 24 is arranged at the opening of the second overflow groove 22, the third chamfer 14 and the fourth chamfer 24 form a second channel 50, the third chamfer 14 and the fourth chamfer 24 are arranged in parallel, and the distance between the third chamfer and the fourth chamfer is 10-50 mu m, so that a thin wall is formed between the formed sealing ring and the second overflow groove 22, and the sealing ring is convenient to take down; the first channel 40 and the second channel 50 are provided to facilitate the removal of the remnants (burrs left on the sealing rings after the sealing rings are formed) in the first overflow chute 12 and the second overflow chute 22 from the sealing rings.

The inner side wall of the annular groove 11 is concave outwards, the bottom of the annular groove is concave downwards, the outer side wall of the annular bulge 21 is concave inwards, the joint of the annular bulge and the upper template 20 is concave upwards, the annular bulge and the upper template form a forming cavity 30 of an O-shaped ring, and fluid plastic material enters the forming cavity 30 to form the O-shaped sealing ring; the mold of the invention further comprises positioning columns which are all conventional means and are not described in detail herein.

The forming units are composed of a plurality of forming cavities 30, flow guide grooves 15 are formed in the periphery of each forming unit, the flow guide grooves 15 are formed in the upper end face of the lower template 10, second overflow grooves 22 in the forming units are communicated with each other, after the upper and lower die assemblies are combined, the second overflow grooves 22 are communicated with the flow guide grooves 15, if a plurality of groups of forming units exist, the flow guide grooves 15 among the forming units are communicated with each other, namely, during production, plastic materials are placed on the upper end face of the lower template 10 and cover the end faces of the forming cavities 30, the upper template 20 is close to the lower template 10 to carry out hot pressing, the plastic materials are melted into a fluid shape, the fluid plastic materials enter the forming cavities 30, redundant plastic materials are left in the second overflow grooves 22 and the flow guide grooves 15, the plastic materials left in the second overflow grooves 22 connect sealing rings (forming completion) in the forming cavities 30 in a single forming unit, the plastic materials left in the flow guide grooves 15 connect the sealing rings in the forming units, after hot pressing, one corner of the plastic materials can be pulled upwards, all sealing rings which are taken out, the formed, the time is saved, and the production efficiency is improved.

In a second aspect, please refer to fig. 7 to 10, which are provided by the present invention, a forming cutter 60 is used for processing the annular groove 11 and the annular protrusion 21 in the first aspect, the forming cutter 60 includes a cutter handle 61 and a forming cutter head 63 connected to a numerical control center, the cutter handle 61 and the forming cutter head 63 are connected through a transition portion 62, the forming cutter head 63 is disposed at 135 degrees, and the end is in a semi-circular shape, the center of the specific forming cutter head 63 and the center of the cutter handle 61 are 135 degrees, i.e., are fixedly connected to the transition portion 62 at 45 degrees downward, the same sides of the transition portion 62 and the forming cutter head 63 are both flush with one side of the cutter handle 61, two ends of the forming cutter head 63 are disposed as inclined surfaces 10b, the cross-sectional area of the forming cutter head 63 is gradually reduced from the side flush with the cutter handle 61 to the side away from the side flush with the cutter handle 61, and the end surface of the forming cutter head 63 is disposed as an arc surface.

The specific use mode of the forming cutter 60 is as follows: in the manufacturing of the O-shaped sealing ring, the upper template 20 and the lower template 10 are required to be matched and then injected with glue. When the O-shaped sealing ring outer cavity scraping device is used, one side, which is flush with the tool holder 61, of the forming tool bit 63 is driven by the machine table to abut against the side wall of a template to be machined, tool setting is carried out, after the tool setting is finished, the tool holder 61 is used as the origin of a coordinate axis, and the forming tool bit 63 is flush with one side of the tool holder 61, so that the position of the forming tool bit 63 can be easily positioned, the positioning accuracy is ensured, the forming tool bit 63 is obliquely arranged at an angle of 45 degrees downwards, and if the upper template 20 is scraped, the position, which faces the middle of the upper template 20, of the forming tool bit 63 is adjusted, so that the outer cavity of the upper template 20 of the O-shaped sealing ring can be scraped anticlockwise conveniently; if the lower template 10 is scraped, the molding cutter head 63 is adjusted to face a direction away from the lower template 10, so that the inner cavity of the lower template 10 of the 0-shaped sealing ring can be scraped clockwise conveniently; the upper and lower templates 10 of the O-shaped sealing ring can be processed by only one cutter, so that the effects of simple process and guaranteed processing precision are achieved.

In a third aspect, please refer to fig. 7 to 12, which are forming processes of an O-ring mold according to the present invention, including forming an annular groove 11 and forming an annular protrusion 21, where the annular groove 11 is integrally formed on the lower mold plate 10, and the annular protrusion 21 is integrally formed on the upper mold plate 20.

Wherein the forming of the annular groove 11 comprises the following steps:

sa1, machining circular groove 10a: machining the circular groove 10a with a milling cutter;

sa2, machined slope 10b: boring the inner side wall of the circular groove 10a by using a cutter with a 45-degree inclined surface 10b, so that the opening of the inner side wall is outward to form the inclined surface 10b, and the bottom of the circular groove 10a forms a first overflow groove 12;

sa3, machining the annular groove 11: scraping the inclined surface 10b with a forming cutter 60 of the second aspect such that an upper portion of the inclined surface 10b is concave outward and a lower portion is concave downward and forms an annular groove 11 having a semicircular cross section;

sa4, machining the first chamfer 13 and the third chamfer 14, and machining the first chamfer 13 and the third chamfer 14 at corresponding positions by using a chamfering tool.

The forming of the annular projection 21 comprises the following steps:

sb1, processing a circular boss 20a, processing the circular boss 20a by using a milling cutter, and forming a second overflow groove 22 around the circular boss 20 a;

sb2, machining a conical table 20b, boring the outer side wall of the circular boss 20a by using a cutter with a 45-degree inclined plane 10b, and forming the conical table 20b on the outer side wall;

sb3, processing of an annular bulge 21: scraping the tapered land 20b with a forming cutter 60 of the second aspect such that the upper portion of the tapered land 20b is concave inward and the lower portion is concave downward and forms an annular projection 21 whose both sides in cross section are semicircular;

sb4, the second chamfer 23 and the fourth chamfer 24 are machined, and the second chamfer 23 and the fourth chamfer 24 are respectively machined at corresponding positions by a chamfering tool.

In the forming process, when the annular groove 11 is processed, the forming cutter 60 scrapes clockwise; when the annular boss is machined, the forming cutter 60 scrapes anticlockwise; the prior art is adopted when the circular groove 10a, the inclined surface 10b, the first chamfer 13, the third chamfer 14, the circular boss 20a, the tapered table 20b, the second chamfer 23 and the fourth chamfer 24 are processed, and therefore detailed description is omitted.

In conclusion, the O-shaped seal ring die provided by the invention has the advantages that the integrated upper die plate and lower die plate are arranged, and the corresponding forming cutter and the forming process are matched at the same time, so that the processing period of the die can be shortened, and the production efficiency is improved.

The invention has been described above with reference to the accompanying drawings, it is obvious that the invention is not limited to the specific implementation in the above-described manner, and it is within the scope of the invention to apply the inventive concept and solution to other applications without substantial modification.

Claims

1. The O-shaped sealing ring die is characterized by comprising a lower die plate and an upper die plate, wherein the lower die plate and the upper die plate are mutually matched to form at least one forming cavity for forming an O-shaped sealing ring, the forming cavity comprises an annular groove arranged on the upper end surface of the lower die plate and an annular bulge which is arranged on the lower end surface of the upper die plate and matched with the annular groove, the annular bulge and the upper die plate are of an integrated structure, the inner side wall of the annular groove is concave outwards, the bottom of the annular bulge is concave downwards, the outer side wall of the annular bulge is concave inwards, the joint of the annular bulge and the upper die plate is concave upwards, and the annular bulge and the upper die plate form a forming cavity of the O-shaped ring;

second overflow chutes are formed in the end face, close to the lower template, of the upper template and positioned on the periphery of the annular bulge; a third chamfer is arranged at the opening of the annular groove, a fourth chamfer is arranged at the opening of the second overflow groove, and the third chamfer and the fourth chamfer form a second channel; the third chamfer and the fourth chamfer are arranged in parallel, and the distance between the third chamfer and the fourth chamfer is 10-50um;

the periphery of the forming unit is provided with a diversion trench, the diversion trench is arranged on the upper end surface of the lower template, and the second overflow groove is communicated with the diversion trench;

a first overflow groove is formed in the lower template and positioned at the bottom of the annular groove; a first chamfer is arranged at the opening of the first overflow groove, a second chamfer is arranged around the end face, close to the lower template, of the annular bulge, a first channel is formed by the first chamfer and the second chamfer, the first chamfer and the second chamfer are arranged in parallel, and the distance between the first chamfer and the second chamfer is 10-50 mu m;

the annular groove forming comprises the following steps:

sa3, processing an annular groove: scraping the inclined plane by using a forming cutter, so that the upper part of the inclined plane is concave outwards and the lower part of the inclined plane is concave downwards to form an annular groove with a semicircular cross section;

the annular bulge forming comprises the following steps:

sb3, processing an annular bulge: scraping the conical table by using a forming cutter, so that the upper part of the conical table is inwards concave and the lower part of the conical table is downwards concave to form annular bulges with semicircular cross sections at two sides;

the shaping sword is including being used for handle of a knife and the shaping tool bit that is connected with numerical control center, the handle of a knife passes through transition portion with the shaping tool bit and is connected, the shaping tool bit is 135 degrees settings, and the end is the semicircle form.