CN212498731U

CN212498731U - Forming die for vertical support of spherical network camera

Info

Publication number: CN212498731U
Application number: CN202020714750.6U
Authority: CN
Inventors: 马东亮; 柏宝兰; 敦春壁; 李东岐
Original assignee: Jiaxing Hezu Electromechanical Equipment Co ltd
Current assignee: Jiaxing Hezu Electromechanical Equipment Co ltd
Priority date: 2020-04-30
Filing date: 2020-04-30
Publication date: 2021-02-09
Anticipated expiration: 2030-04-30

Abstract

A spherical network camera vertical support forming die comprises an upper die base, a lower die base, an upper die, a lower die, a pouring assembly and a supporting plate forming mechanism; the upper die is provided with a forming lug in a protruding way; the lower die is provided with a first forming groove; the two sides of the lower die seat are provided with first openings, the two sides of the lower die are provided with second openings, and the supporting plate forming mechanism comprises two supporting plate forming units which are partially positioned in the first openings and the second openings; the upper die is provided with two material inlet grooves, and one side of each material inlet groove, which faces the forming lug, is provided with a plurality of feeding buffer grooves; the upper die is provided with a plurality of first outflow buffer grooves and a guide-out groove communicated with at least two first outflow buffer grooves; the upper die is provided with a plurality of independent second outflow buffer grooves; the lower die is provided with a plurality of second outflow buffer grooves and material outflow grooves. So can realize chassis and backup pad integrated into one piece, form the shaft hole simultaneously, reduce and the inflow and the outflow pressure of homogenization material, avoid the object to warp.

Description

Forming die for vertical support of spherical network camera

Technical Field

The utility model relates to a security protection control technical field, especially a spherical network camera vertical stand forming die.

Background

Referring to fig. 1 and 2, the vertical stand of the dome camera includes a substantially circular chassis 101 and a support plate 102 vertically connected to two sides of the chassis 101 and extending in the same direction, wherein the support plate 102 is provided with a shaft hole 103. In manufacturing the vertical stand of the dome camera using the mold, it is necessary to form the base plate 101 integrally with the support plate 102 and simultaneously form the shaft hole 103 on the support plate 102. But the demolding direction of the chassis 101 and the demolding direction of the support plate 102 are exactly perpendicular, which puts high demands on the mold implementation. In addition, in the existing mold, when the material enters the mold through the runner inlet, the fluid pressure of the material is high, and the shape of the formed object can also deform due to impact pressure; the shape of the material is deformed through a single runner outlet, and the quality is difficult to ensure.

SUMMERY OF THE UTILITY MODEL

In view of this, the utility model provides a can realize chassis and backup pad integrated into one piece, form the shaft hole simultaneously, reduce and the inflow and the outflow pressure of homogenization material, avoid the spherical network camera vertical stand forming die of object deformation to solve above-mentioned problem.

A spherical network camera vertical support forming die comprises an upper die base, a lower die base, an upper die, a lower die, a pouring assembly and a supporting plate forming mechanism; the upper die holder is movably positioned above the lower die holder, the bottom surface of the upper die holder is provided with an upper die cavity, and the upper die is positioned in the upper die cavity; the top surface of the lower die base is provided with a lower die cavity, and the lower die is positioned in the lower die cavity; the upper die base is provided with a pouring port communicated with the upper die cavity, and the pouring assembly is positioned in the pouring port; a forming lug is arranged in the middle of the bottom surface of the upper die in a protruding manner; a first forming groove is formed in the middle of the top surface of the lower die; first openings are respectively formed in the lower die base on two sides of the lower die cavity, second openings corresponding to the first openings are formed in two sides of the lower die, and the second openings are communicated with the first forming grooves; the supporting plate forming mechanism comprises two supporting plate forming units which are respectively and movably arranged at two sides of the first forming groove, and each supporting plate forming unit is partially arranged in the first opening and the second opening; the upper die is provided with a first avoidance port at one side of the forming lug, the upper die is also provided with two material inlet grooves which are communicated with the first avoidance port and are positioned at the outer side of the forming lug, and the material inlet grooves are provided with a plurality of feeding buffer grooves at one side facing the forming lug; the upper die is provided with a plurality of first outflow buffer grooves on two sides of the forming lug, and is also provided with a leading-out groove communicated with at least two first outflow buffer grooves, and the tail end of the leading-out groove is close to one side of the upper die, which is far away from the first avoidance port; the upper die is also provided with a plurality of independent second outflow buffer grooves on one side of the forming lug, which is far away from the first avoidance port; the lower die is provided with a second avoidance port corresponding to the first avoidance port, and the lower die is provided with a plurality of second outflow buffer grooves and material outflow grooves communicated with the second outflow buffer grooves on one side of the first forming groove.

Furthermore, each supporting plate forming unit comprises a driving mechanism, two guide blocks vertically connected with the outer surfaces of the two sides of the first opening respectively, a sliding block connected with the output end of the driving mechanism and connected with the two guide blocks in a sliding manner, a forming block connected with the sliding block and a forming column penetrating through the forming block, wherein a second forming groove is formed in one side, away from the driving mechanism, of the forming block, and the forming column protrudes out of the forming block.

Furthermore, a first diversion trench is obliquely arranged between the feeding buffer trench and the forming bump.

Furthermore, a second diversion trench is obliquely arranged between the first outflow buffer trench and the forming bump.

Furthermore, a third diversion trench is obliquely arranged between the second outflow buffer trench and the forming bump.

Furthermore, an upper buffer block mounting groove communicated with the upper die cavity is formed in one side, away from the first avoidance port, of the upper die base, an upper buffer block is located in the upper buffer block mounting groove, the bottom surface of the upper buffer block is flush with the bottom surface of the upper die, and a plurality of first overflow grooves are formed in the upper buffer block in a recessed mode; the lower die base is provided with a lower buffer block mounting groove in a concave mode on one side, away from the second avoidance port, of the lower die cavity, the lower buffer block is located in the lower buffer block mounting groove, the top surface of the lower buffer block is flush with the top surface of the lower die, a second overflow groove communicated with the material outflow groove is formed in the lower buffer block in a concave mode, and a connecting groove is connected between the second overflow groove and the material outflow groove; the top surface of the lower buffer block is provided with a plurality of embedded blocks in a protruding manner, each embedded block is positioned in a first overflow groove, and a gap is formed between each embedded block and the first overflow groove.

Furthermore, the pouring assembly comprises a guide column which is arranged on the lower die base in a protruding mode and is located in the pouring gate, and a sleeve which is sleeved on the guide column and is located in the pouring gate, and a guide groove is formed in one side, facing the lower die cavity, of the guide column.

Further, the material inlet groove is distributed at the outer side of the forming lug by an angle smaller than 180 degrees.

Compared with the prior art, the forming die for the vertical bracket of the spherical network camera comprises an upper die base, a lower die base, an upper die, a lower die, a pouring component and a supporting plate forming mechanism; the upper die holder is movably positioned above the lower die holder, the bottom surface of the upper die holder is provided with an upper die cavity, and the upper die is positioned in the upper die cavity; the top surface of the lower die base is provided with a lower die cavity, and the lower die is positioned in the lower die cavity; the upper die base is provided with a pouring port communicated with the upper die cavity, and the pouring assembly is positioned in the pouring port; a forming lug is arranged in the middle of the bottom surface of the upper die in a protruding manner; a first forming groove is formed in the middle of the top surface of the lower die; first openings are respectively formed in the lower die base on two sides of the lower die cavity, second openings corresponding to the first openings are formed in two sides of the lower die, and the second openings are communicated with the first forming grooves; the supporting plate forming mechanism comprises two supporting plate forming units which are respectively and movably arranged at two sides of the first forming groove, and each supporting plate forming unit is partially arranged in the first opening and the second opening; the upper die is provided with a first avoidance port at one side of the forming lug, the upper die is also provided with two material inlet grooves which are communicated with the first avoidance port and are positioned at the outer side of the forming lug, and the material inlet grooves are provided with a plurality of feeding buffer grooves at one side facing the forming lug; the upper die is provided with a plurality of first outflow buffer grooves on two sides of the forming lug, and is also provided with a leading-out groove communicated with at least two first outflow buffer grooves, and the tail end of the leading-out groove is close to one side of the upper die, which is far away from the first avoidance port; the upper die is also provided with a plurality of independent second outflow buffer grooves on one side of the forming lug, which is far away from the first avoidance port; the lower die is provided with a second avoidance port corresponding to the first avoidance port, and the lower die is provided with a plurality of second outflow buffer grooves and material outflow grooves communicated with the second outflow buffer grooves on one side of the first forming groove. So can realize chassis and backup pad integrated into one piece, form the shaft hole simultaneously, reduce and the inflow and the outflow pressure of homogenization material, avoid the object to warp.

Drawings

Embodiments of the present invention are described below with reference to the accompanying drawings, in which:

fig. 1 is a perspective view of a first view angle of a vertical stand of a dome webcam.

Fig. 2 is a perspective view of a second perspective view of a vertical mount of a dome webcam.

Fig. 3 is the utility model provides a vertical support forming die's of spherical network camera three-dimensional schematic diagram.

Fig. 4 is a schematic perspective view of the forming mold for vertical stand of spherical network camera in fig. 3 with the upper mold base removed.

Fig. 5 is a schematic perspective view of the vertical stand forming mold for a dome webcam shown in fig. 4 with an upper mold removed.

Fig. 6 is a perspective view of the support plate forming mechanism and the lower mold in fig. 5.

Fig. 7 is a perspective view of the support plate forming mechanism of fig. 6 with the forming block removed.

Fig. 8 is a perspective view of the upper die holder and the upper die.

Fig. 9 is a perspective view of the upper die.

FIG. 10 is a perspective view of the lower mold base and the lower mold.

Detailed Description

The following describes in further detail specific embodiments of the present invention based on the drawings. It should be understood that the description herein of embodiments of the invention is not intended to limit the scope of the invention.

Referring to fig. 3 to 5, the mold for forming a vertical stand of a dome camera according to the present invention includes an upper mold base 10, a lower mold base 20, an upper mold 30, a lower mold 40, a casting assembly 50, and a support plate forming mechanism 60.

The upper die holder 10 is movably positioned above the lower die holder 20, the bottom surface of the upper die holder 10 is provided with an upper die cavity, and the upper die 30 is positioned in the upper die cavity; the top surface of the lower die holder 20 has a lower die cavity in which the lower die 40 is located.

The upper die base 10 is provided with a pouring gate communicated with the upper die cavity, and the pouring assembly 50 is positioned in the pouring gate.

The casting assembly 50 includes a flow guiding column protruding from the lower die base 20 and located in the pouring gate 11, and a sleeve sleeved on the flow guiding column and located in the pouring gate. One side of the flow guide column facing the lower die cavity is provided with a flow guide groove 51 for guiding the material into the lower die 40.

Referring to fig. 9, a molding protrusion 31 protrudes from the middle of the bottom surface of the upper mold 30.

Referring to fig. 10, a first forming groove 41 is formed in the middle of the top surface of the lower mold 40.

The lower die holder 20 is provided with first openings 22 at two sides of the lower die cavity, and two sides of the lower die 40 are provided with second openings 42 corresponding to the first openings 22, wherein the second openings 42 are communicated with the first forming grooves 41.

Referring to fig. 6 and 7, the supporting plate forming mechanism 60 includes two supporting plate forming units respectively disposed at two sides of the first forming groove 41, and each supporting plate forming unit is partially disposed in the first opening 22 and the second opening 42.

Each support plate forming unit comprises a driving mechanism 61, two guide blocks 62 respectively vertically connected with the outer surfaces of two sides of the first opening 22, a sliding block 63 connected with the two guide blocks 62 in a sliding way and connected with the output end of the driving mechanism 61, a forming block 64 connected with the sliding block 63 and a forming column 65 penetrating through the forming block 64.

The side of the forming block 64 away from the driving mechanism 61 is provided with a second forming groove for forming the supporting plate 102; the forming post 65 protrudes from the forming block 64 for forming the shaft hole 103.

Referring to fig. 8 and 9, the upper mold 30 is provided with a first avoiding opening 301 communicated with the guiding groove 51 at one side of the forming protrusion 31, and is further provided with two material inlet grooves 32 communicated with the first avoiding opening 301 and located at the outer side of the forming protrusion 31, wherein the material inlet grooves 32 are provided with a plurality of feeding buffer grooves 321 at one side facing the forming protrusion 31, and the first guiding groove 322 is obliquely arranged between the feeding buffer grooves 321 and the forming protrusion 31.

The material inlet groove 32 is distributed at an angle of less than 180 degrees, preferably 120 degrees, outside the forming lug 31.

The upper mold 30 is further provided with a plurality of first outflow buffer grooves 33 separated from the material inflow groove 32 on both sides of the forming protrusion 31, and a second diversion groove 331 is obliquely arranged between the first outflow buffer grooves 33 and the forming protrusion 31.

The upper die 30 is further provided with a lead-out groove 332 communicating with the at least two first outflow buffer grooves 33, and the end of the lead-out groove 332 is close to the side of the upper die 30 far away from the first avoidance port 301.

The upper mold 30 is further provided with a plurality of independent second outflow buffer grooves 34 on a side of the molding protrusion 31 away from the first avoiding opening 301, and a third diversion groove 341 is obliquely arranged between the second outflow buffer grooves 34 and the molding protrusion 31.

An upper buffer block mounting groove communicated with the upper die cavity is formed in one side, away from the first avoidance port 301, of the upper die base 10, and an upper buffer block 70 is located in the upper buffer block mounting groove. The bottom surface of the upper cushion block 70 is flush with the bottom surface of the upper die 30. The upper buffer block 70 is concavely provided with a plurality of first overflow chutes 71.

Referring to fig. 10, a lower die base 20 is provided with a guiding pillar mounting groove 21 at one side of the lower die cavity, and the guiding pillar is located in the guiding pillar mounting groove 21. A second avoidance opening 401 is formed at one side of the lower die 40 facing the guide column installation groove 21.

The lower mold 40 has a plurality of second outflow buffer grooves 43 and a material outflow groove 44 communicating with the second outflow buffer grooves 43 at one side of the first molding groove 41.

Lower die holder 20 is provided with down the buffer block mounting groove in the sunken one side of keeping away from water conservancy diversion post mounting groove 21 of lower mould chamber, and buffer block 80 is located down in the buffer block mounting groove. The top surface of the lower cushion block 80 is flush with the top surface of the lower die 40. The lower buffer block 80 is concavely provided with a second overflow groove 81 communicated with the material outflow groove 44, and a connecting groove 82 is connected between the second overflow groove 81 and the material outflow groove 44.

The top surface of the lower buffer block 80 is protrudingly provided with a plurality of insert blocks 83, each insert block 83 is located in a first overflow groove 71, and a gap is formed between each insert block 83 and the first overflow groove 71.

Referring to fig. 5 again, the bottom of the lower die base 20 is further provided with a lifting plate 90, a plurality of ejector pins 91 vertically disposed on the lifting plate 90 and penetrating through the lower die base 20 and the lower die 40, and a lifting driving unit for driving the lifting plate to move up and down. The lift-up driving unit drives the lift-up plate 90 and the ejector pin 91 to move upward to lift up and release the vertical holder of the dome camcorder formed in the lower mold 40.

Compared with the prior art, the forming die for the vertical bracket of the spherical network camera comprises an upper die base 10, a lower die base 20, an upper die 30, a lower die 40, a pouring component 50 and a supporting plate forming mechanism 60; the upper die holder 10 is movably positioned above the lower die holder 20, the bottom surface of the upper die holder 10 is provided with an upper die cavity, and the upper die 30 is positioned in the upper die cavity; the top surface of the lower die holder 20 is provided with a lower die cavity, and the lower die 40 is positioned in the lower die cavity; a pouring gate communicated with the upper die cavity is formed in the upper die base 10, and the pouring assembly 50 is positioned in the pouring gate; a molding lug 31 is convexly arranged in the middle of the bottom surface of the upper die 30; a first forming groove 41 is formed in the middle of the top surface of the lower die 40; the lower die base 20 is respectively provided with first openings 22 at two sides of the lower die cavity, two sides of the lower die 40 are provided with second openings 42 corresponding to the first openings 22, and the second openings 42 are communicated with the first forming grooves 41; the supporting plate forming mechanism 60 includes two supporting plate forming units movably disposed at two sides of the first forming groove 41, respectively, and each supporting plate forming unit is partially disposed in the first opening 22 and the second opening 42; the upper die 30 is provided with a first avoiding opening 301 at one side of the forming bump 31, the upper die 30 is further provided with two material inlet grooves 32 which are communicated with the first avoiding opening 301 and are positioned at the outer side of the forming bump 31, and one side of the material inlet grooves 32 facing the forming bump 31 is provided with a plurality of material inlet buffer grooves 321; the upper die 30 is provided with a plurality of first outflow buffer grooves 33 on two sides of the forming bump 31, and is provided with a leading-out groove 332 communicated with at least two first outflow buffer grooves 33, and the tail end of the leading-out groove 332 is close to one side of the upper die 30 far away from the first avoidance port 301; the upper die 30 is further provided with a plurality of independent second outflow buffer grooves 34 on one side of the forming lug 31 away from the first avoidance port 301; the lower mold 40 is provided with a second avoiding opening 401 corresponding to the first avoiding opening 301, and the lower mold 40 is provided with a plurality of second outflow buffer grooves 43 and material outflow grooves 44 communicated with the second outflow buffer grooves 43 at one side of the first forming groove 41. The chassis and the supporting plate can be integrally formed, the shaft holes are formed at the same time, the inflow and outflow pressure of materials is reduced and homogenized, and the deformation of objects is avoided; realize that backup pad and chassis are demolded respectively in proper order.

The above description is only for the preferred embodiment of the present invention and should not be construed as limiting the scope of the present invention, and any modification, equivalent replacement or improvement within the spirit of the present invention is encompassed by the claims of the present invention.

Claims

1. The utility model provides a vertical support forming die of spherical network camera which characterized in that: comprises an upper die holder, a lower die holder, an upper die, a lower die, a pouring assembly and a supporting plate forming mechanism; the upper die holder is movably positioned above the lower die holder, the bottom surface of the upper die holder is provided with an upper die cavity, and the upper die is positioned in the upper die cavity; the top surface of the lower die base is provided with a lower die cavity, and the lower die is positioned in the lower die cavity; the upper die base is provided with a pouring port communicated with the upper die cavity, and the pouring assembly is positioned in the pouring port; a forming lug is arranged in the middle of the bottom surface of the upper die in a protruding manner; a first forming groove is formed in the middle of the top surface of the lower die; first openings are respectively formed in the lower die base on two sides of the lower die cavity, second openings corresponding to the first openings are formed in two sides of the lower die, and the second openings are communicated with the first forming grooves; the supporting plate forming mechanism comprises two supporting plate forming units which are respectively and movably arranged at two sides of the first forming groove, and each supporting plate forming unit is partially arranged in the first opening and the second opening; the upper die is provided with a first avoidance port at one side of the forming lug, the upper die is also provided with two material inlet grooves which are communicated with the first avoidance port and are positioned at the outer side of the forming lug, and the material inlet grooves are provided with a plurality of feeding buffer grooves at one side facing the forming lug; the upper die is provided with a plurality of first outflow buffer grooves on two sides of the forming lug, and is also provided with a leading-out groove communicated with at least two first outflow buffer grooves, and the tail end of the leading-out groove is close to one side of the upper die, which is far away from the first avoidance port; the upper die is also provided with a plurality of independent second outflow buffer grooves on one side of the forming lug, which is far away from the first avoidance port; the lower die is provided with a second avoidance port corresponding to the first avoidance port, and the lower die is provided with a plurality of second outflow buffer grooves and material outflow grooves communicated with the second outflow buffer grooves on one side of the first forming groove.

2. The spherical network camera vertical stand forming die of claim 1, wherein: each backup pad shaping unit includes actuating mechanism, two guide blocks that are connected with first open-ended both sides surface is perpendicular respectively, with two equal sliding connection of guide block and with the sliding block that actuating mechanism's output is connected, the shaping piece that is connected with the sliding block and pass the shaping post of shaping piece, one side that actuating mechanism was kept away from to the shaping piece has the second shaping groove, the shaping post salient in the shaping piece.

3. The spherical network camera vertical stand forming die of claim 1, wherein: a first diversion trench is obliquely arranged between the feeding buffer trench and the forming bump.

4. The spherical network camera vertical stand forming die of claim 1, wherein: and a second diversion trench is obliquely arranged between the first outflow buffer trench and the forming bump.

5. The spherical network camera vertical stand forming die of claim 1, wherein: and a third diversion trench is obliquely arranged between the second outflow buffer trench and the forming bump.

6. The spherical network camera vertical stand forming die of claim 1, wherein: an upper buffer block mounting groove communicated with the upper die cavity is formed in one side, away from the first avoidance port, of the upper die base, an upper buffer block is located in the upper buffer block mounting groove, the bottom surface of the upper buffer block is flush with the bottom surface of the upper die, and a plurality of first overflow grooves are formed in the upper buffer block in a recessed mode; the lower die base is provided with a lower buffer block mounting groove in a concave mode on one side, away from the second avoidance port, of the lower die cavity, the lower buffer block is located in the lower buffer block mounting groove, the top surface of the lower buffer block is flush with the top surface of the lower die, a second overflow groove communicated with the material outflow groove is formed in the lower buffer block in a concave mode, and a connecting groove is connected between the second overflow groove and the material outflow groove; the top surface of the lower buffer block is provided with a plurality of embedded blocks in a protruding manner, each embedded block is positioned in a first overflow groove, and a gap is formed between each embedded block and the first overflow groove.

7. The spherical network camera vertical stand forming die of claim 1, wherein: the pouring assembly comprises a guide column which is arranged on the lower die base in a protruding mode and is located in the pouring gate, and a sleeve which is sleeved on the guide column and is located in the pouring gate, and a guide groove is formed in one side, facing the lower die cavity, of the guide column.

8. The spherical network camera vertical stand forming die of claim 1, wherein: the material inlet groove is distributed at the outer side of the forming lug by an angle smaller than 180 degrees.