CN210791859U - Forming die of mirror leg support - Google Patents

Abstract

A forming die for a glasses leg bracket comprises an upper die device and a lower die device, wherein the upper die device comprises an upper die plate and an upper forming plate embedded at the bottom of the upper die plate, the lower die device comprises a lower die plate, a lower forming plate embedded on the lower die plate and opposite to the upper forming plate, and a forming module arranged on the lower die plate and positioned at the side part of the lower forming plate; the upper die device and the lower die device are provided with driving devices which enable the forming modules to be embedded into and separated from the forming grooves; the driving device comprises a sliding block arranged on the lower template, an elastic component arranged on the lower template and used for driving the sliding block to move outwards, and an inclined rod arranged on the upper template and used for driving the sliding block to move inwards; the shaping module sets up on the medial surface of slider, is equipped with the direction chute on the slider, and in the down tube stretched into the direction chute, the down tube was located the lateral part of last shaping board, and the down tube gradually increased from top to bottom with the horizontal distance of last shaping board. The utility model discloses can be used for producing corresponding mirror leg support.

Description

Forming die of mirror leg support

Technical Field

The utility model relates to a forming die of mirror leg support.

Background

Fig. 8 shows an attachment of a massage eye cup (hereinafter referred to as a temple holder 37), the temple holder 37 includes a base plate 42 and side plates 43 attached to the upper, front and rear portions of the base plate 42, and in order to produce the temple holder 37 of such a structure, a corresponding molding die is designed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a forming die of mirror leg support, it can be used for producing corresponding mirror leg support.

The purpose of the utility model is realized like this:

a forming die for a glasses leg bracket comprises an upper die device and a lower die device which are matched with each other, wherein the upper die device comprises an upper die plate and an upper forming plate embedded at the bottom of the upper die plate;

the upper die device and the lower die device are provided with driving devices for driving the forming modules to transversely move so as to enable the forming modules to be embedded into and separated from the forming grooves;

the driving device comprises a sliding block arranged on the lower template, an elastic component arranged on the lower template and used for driving the sliding block to move outwards, and an inclined rod arranged on the upper template and used for driving the sliding block to move inwards;

the forming module is arranged on the inner side face of the sliding block, a guide chute is arranged on the sliding block, the inclined rod extends into the guide chute, the inclined rod is located on the side portion of the upper forming plate, and the horizontal distance between the inclined rod and the upper forming plate is gradually increased from top to bottom.

The lower template is provided with a transverse sliding groove corresponding to the sliding block, the sliding block is arranged in the transverse sliding groove, and the outer side of the transverse sliding groove penetrates through the corresponding side part of the lower template.

The elastic component comprises an installation plate, a bolt, a spring and a cushion block, wherein the installation plate is embedded at the side part of the lower template and is positioned above the outer side of the transverse sliding chute;

the tail part of the bolt penetrates through the mounting plate and is rotatably arranged on the outer side of the sliding block, one end of the spring is in transmission connection with the outer side face of the mounting plate, and the other end of the spring is in transmission connection with the cushion block.

The upper die device comprises a top plate arranged on the upper die plate;

the upper template is provided with an installation chute, a sink groove coaxially connected to the installation chute and a counter bore connected to the sink groove corresponding to the inclined rod, the counter bore penetrates through the upper surface of the upper template, and the installation chute penetrates through the bottom of the upper template;

the coaxial location platform that is provided with in down tube upper end, the diameter of location platform is greater than the diameter of down tube, and the location platform sets up in the heavy inslot, and the installation chute is worn out downwards to the down tube, and the counter bore is embedded to be equipped with the clamp plate.

The lower die device comprises a lower base plate arranged at the bottom of the lower die plate and a bottom plate arranged at the bottom of the lower base plate.

The molding module comprises a vertical plate fixed on the inner side surface of the sliding block, a first molding boss arranged on the inner side surface of the vertical plate and a second molding boss arranged on the inner side surface of the second molding boss;

the shaping recess is including setting up the first holding tank and the connection at the inboard second holding tank of first holding tank at last shaping board lateral part.

When the molding module is embedded into the molding groove, the vertical plate is embedded into the first accommodating groove, and the first molding boss and the second molding boss are embedded into the second accommodating groove;

the inner wall of the first accommodating groove is respectively attached and connected with the upper surface, the front surface, the rear surface and the inner side surface of the vertical plate;

the inner wall of the second accommodating groove is respectively attached to the upper surface, the front surface and the rear surface of the first forming boss;

and spacing intervals for molding are reserved between the inner wall of the second accommodating groove and the upper surface, the front surface, the rear surface and the inner side surface of the second molding boss respectively.

A positioning block is arranged at the bottom of the first forming boss, and the outer side of the positioning block is connected with the vertical plate;

the side part of the upper surface of the lower forming plate is provided with a first positioning groove corresponding to the vertical plate, and the first positioning groove is positioned on the inner side of the sliding block;

a second positioning groove connected to the inner side of the first positioning groove is formed in the upper surface of the lower forming plate corresponding to the positioning block, and the first forming boss and the second forming boss are located above the first positioning groove and the second positioning groove;

when the molding module is embedded into the molding groove, the lower part of the vertical plate is embedded into the first positioning groove, and the positioning block is embedded into the second positioning groove.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

Fig. 1 is an exploded view of an embodiment of the present invention.

Fig. 2 is an exploded view of an embodiment of the present invention.

Fig. 3 is a partially enlarged view of the portion of fig. 1A.

Fig. 4 is a cross-sectional view of an embodiment of the present invention.

Fig. 5 is a schematic structural view of an upper forming plate according to an embodiment of the present invention.

Fig. 6 is a schematic structural view of a lower molding plate according to an embodiment of the present invention.

Fig. 7 is a schematic structural diagram of a molding module according to an embodiment of the present invention.

Fig. 8 is a schematic view of the construction of the temple holder.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and examples.

Referring to fig. 1 to 8, the forming mold for the temple bracket includes an upper mold device 1 and a lower mold device 2 which are matched with each other, the upper mold device 1 includes an upper mold plate 3 and an upper forming plate 4 embedded at the bottom of the upper mold plate 3, the lower mold device 2 includes a lower mold plate 5, a lower forming plate 6 embedded on the lower mold plate 5 and opposite to the upper forming plate 4, and a forming module 7 arranged on the lower mold plate 5 and located at the side of the lower forming plate 6;

the present molding die can be used to produce the corresponding temple bracket 37.

The side part of the upper forming plate 4 is provided with a forming groove 8, and the upper die device 1 and the lower die device 2 are provided with driving devices for driving the forming module 7 to transversely move so as to enable the forming module 7 to be embedded into and separated from the forming groove 8;

the driving device comprises a slide block 9 arranged on the lower template 5, an elastic component arranged on the lower template 5 and used for driving the slide block 9 to move outwards, and an inclined rod 11 arranged on the upper template 3 and used for driving the slide block 9 to move inwards;

the forming module 7 is arranged on the inner side face of the sliding block 9, a guide chute 10 is arranged on the sliding block 9, the inclined rod 11 extends into the guide chute 10, the inclined rod 11 is located on the side portion of the upper forming plate 4, and the horizontal distance between the inclined rod 11 and the upper forming plate 4 is gradually increased from top to bottom.

When the upper die device 1 and the lower die device 2 are closed, the inclined rod 11 drives the slide block 9 to move inwards (namely, the slide block 9 moves towards the direction close to the lower forming plate 6), so that the forming module 7 is embedded into the forming groove 8;

when the upper die device 1 and the lower die device 2 are separated, the inclined rod 11 moves upwards relative to the slide block 9, and simultaneously, the elastic component drives the slide block 9 to move outwards, so that the forming module 7 is separated from the forming groove 8.

Further, a transverse sliding groove 12 is formed in the lower template 5 corresponding to the sliding block 9, the sliding block 9 is arranged in the transverse sliding groove 12, and the outer side of the transverse sliding groove 12 penetrates through the corresponding side portion of the lower template 5. The transverse runner 12 is arranged to guide the movement of the slide 9.

Furthermore, the elastic component comprises an installation plate 13 which is embedded at the side part of the lower template 5 and positioned above the outer side of the transverse chute 12, a bolt 14 arranged on the installation plate 13, a spring 15 and a cushion block 16 which are all sleeved on the bolt 14;

the tail of the bolt 14 penetrates through the mounting plate 13 and is rotatably arranged on the outer side of the sliding block 9, linkage of the bolt 14 and the sliding block 9 is achieved, one end of the spring 15 is in transmission connection with the outer side face of the mounting plate 13, the other end of the spring 15 is in transmission connection with the cushion block 16, and the spring 15 is located between the mounting plate 13 and the cushion block 16.

Further, the upper die device 1 includes a top plate 17 provided on the upper die plate 3;

the upper template 3 is provided with an installation chute 18, a sinking groove 19 coaxially connected to the installation chute 18 and a counter bore 20 connected to the sinking groove 19 corresponding to the inclined rod 11, the counter bore 20 penetrates through the upper surface of the upper template 3, and the installation chute 18 penetrates through the bottom of the upper template 3;

the lower template 5 is provided with a receiving hole 34 which is positioned at the bottom of the slide block 9 and used for receiving the bottom end of the inclined rod 11, and the length of the inclined rod 11 is ensured by the receiving hole 30, so that when the upper die device 1 and the lower die device 2 are in a matched die or separated state, at least part of the inclined rod 11 is positioned on the guide inclined groove 10 of the slide block 9.

The upper end of the diagonal rod 11 is coaxially provided with a positioning table 21, the diameter of the positioning table 21 is larger than that of the diagonal rod 11, the positioning table 21 is arranged in a sinking groove 19, the diagonal rod 11 penetrates through an installation chute 18 downwards, a pressing plate 22 is embedded in a sinking hole 20, positioning and installation of the diagonal rod 11 are achieved, and the diagonal rod 11 moves up and down along with an upper die device.

Further, the lower die device 2 includes a lower backing plate 23 disposed at the bottom of the lower die plate 5 and a bottom plate 24 disposed at the bottom of the lower backing plate 23, and constitutes the lower die device 2 of the forming die.

Furthermore, the forming module 7 comprises a vertical plate 25 fixed on the inner side surface of the sliding block 9, a first forming boss 26 arranged on the inner side surface of the vertical plate 25, and a second forming boss 27 arranged on the inner side surface of the second forming boss 27;

the rear upper corners of the first forming boss 26 and the second forming boss 27 are both transited through an arc 35, and an arc part 36 extending backwards is arranged below the rear parts of the first forming boss 26 and the second forming boss 27.

The forming groove 8 includes a first receiving groove 28 formed at a side portion of the upper forming plate 4 and a second receiving groove 29 connected to an inner side of the first receiving groove 28.

Further, when the molding module 7 is embedded into the molding groove 8, the riser 25 is embedded into the first receiving groove 28, and the first molding boss 26 and the second molding boss 27 are embedded into the second receiving groove 29;

the inner wall of the first accommodating groove 28 is respectively attached to the upper surface, the front surface, the rear surface and the inner side surface of the vertical plate 25;

the inner wall of the second accommodating groove 29 is respectively attached to the upper surface, the front surface and the rear surface of the first forming boss 26;

spacing intervals for molding are reserved among the inner walls of the second accommodating grooves 29 and the upper surface, the front surface, the rear surface and the inner side surface of the second molding bosses 27, the shapes of the spacing intervals are matched with those of the temple supports 37, and the substrates 42 and 43 of the temple supports 37 are machined.

Referring to fig. 1 and 2, an eyeshade frame 41 is arranged between the two temple supports 37, the temple supports 37 are connected to the side portions of the eyeshade frame 41, an upper concave portion 38 is arranged on the bottom surface of the upper forming plate 4, a forming table 39 is arranged on the upper surface of the lower forming plate 6 corresponding to the upper concave portion 38, the forming module 7 and the driving device are arranged on the side portions of the forming table 39, and the forming grooves 8 are arranged on the side portions of the upper concave portion 38.

When the upper mold device 1 and the lower mold device 2 are clamped, a molding cavity for processing the mask frame 41 is formed between the upper concave portion 38 and the molding table 39, and the molding cavity communicates with the interval section, so that the mask frame 41 and the temple holder 37 can be integrally molded.

The injection molding nozzle 40 is embedded in the bottom plate 24, the injection molding nozzle 40 extends upwards to the upper surface of the lower molding plate 6, and the output end of the injection molding nozzle 40 is communicated with the molding cavity for realizing injection molding of the molding mold.

Furthermore, a positioning block 31 is arranged at the bottom of the first forming boss 26, and the outer side of the positioning block 31 is connected with the vertical plate 25;

the side part of the upper surface of the lower forming plate 6 is provided with a first positioning groove 32 corresponding to the vertical plate 25, and the first positioning groove 32 is positioned at the inner side of the sliding block 9; the first positioning groove 32 is connected with the transverse sliding groove 12.

A second positioning groove 33 connected to the inner side of the first positioning groove 32 is formed in the upper surface of the lower molding plate 6 corresponding to the positioning block 31, and the first molding boss 26 and the second molding boss 27 are located above the first positioning groove 32 and the second positioning groove 33;

when the molding module 7 is embedded into the molding groove 8, the lower part of the vertical plate 25 is embedded into the first positioning groove 32, and the positioning block 31 is embedded into the second positioning groove 33.

The matching of the upper part of the first positioning groove 32 and the lower part of the vertical plate 25 and the matching of the second positioning groove 33 and the positioning block 31 improve the stability and the precision of the movement of the forming module 7.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention and not for the purpose of limiting the same, and the appended claims are intended to cover all such modifications, equivalents, and alternatives falling within the scope of the present invention.

Claims (8)

1. The forming die for the glasses leg support is characterized by comprising an upper die device (1) and a lower die device (2) which are matched with each other, wherein the upper die device (1) comprises an upper die plate (3) and an upper forming plate (4) embedded at the bottom of the upper die plate (3), the lower die device (2) comprises a lower die plate (5), a lower forming plate (6) embedded on the lower die plate (5) and opposite to the upper forming plate (4), and a forming module (7) arranged on the lower die plate (5) and located at the side part of the lower forming plate (6);

the side part of the upper forming plate (4) is provided with a forming groove (8), and the upper die device (1) and the lower die device (2) are provided with driving devices for driving the forming module (7) to transversely move so as to enable the forming module (7) to be embedded into and separated from the forming groove (8);

the driving device comprises a sliding block (9) arranged on the lower template (5), an elastic component arranged on the lower template (5) and used for driving the sliding block (9) to move outwards, and an inclined rod (11) arranged on the upper template (3) and used for driving the sliding block (9) to move inwards;

the forming module (7) is arranged on the inner side face of the sliding block (9), a guide chute (10) is arranged on the sliding block (9), an inclined rod (11) extends into the guide chute (10), the inclined rod (11) is located on the side portion of the upper forming plate (4), and the horizontal distance between the inclined rod (11) and the upper forming plate (4) is gradually increased from top to bottom.

2. The forming die for the temple support according to claim 1, wherein the lower template (5) is provided with a transverse sliding groove (12) corresponding to the sliding block (9), the sliding block (9) is arranged in the transverse sliding groove (12), and the outer side of the transverse sliding groove (12) penetrates through the corresponding side of the lower template (5).

3. The forming die for the temple bracket according to claim 2, wherein the elastic component comprises a mounting plate (13) embedded at the side of the lower template (5) and positioned above the outer side of the transverse sliding chute (12), a bolt (14) arranged on the mounting plate (13), a spring (15) and a cushion block (16) which are sleeved on the bolt (14);

the tail of the bolt (14) penetrates through the mounting plate (13) and is rotatably arranged on the outer side of the sliding block (9), one end of the spring (15) is in transmission connection with the outer side face of the mounting plate (13), and the other end of the spring (15) is in transmission connection with the cushion block (16).

4. Mould for forming temple supports according to claim 1, wherein said upper mould means (1) comprises a top plate (17) arranged on an upper mould plate (3);

the upper template (3) is provided with an installation chute (18), a sinking groove (19) coaxially connected to the installation chute (18) and a counter bore (20) connected to the sinking groove (19) corresponding to the inclined rod (11), the counter bore (20) penetrates through the upper surface of the upper template (3), and the installation chute (18) penetrates through the bottom of the upper template (3);

the upper end of the diagonal rod (11) is coaxially provided with a positioning table (21), the diameter of the positioning table (21) is larger than that of the diagonal rod (11), the positioning table (21) is arranged in a sinking groove (19), the diagonal rod (11) penetrates through an installation chute (18) downwards, and a pressing plate (22) is embedded in a sinking hole (20).

5. The temple bracket molding die according to claim 1, wherein the lower die means (2) comprises a lower pad (23) provided at the bottom of the lower mold plate (5) and a bottom plate (24) provided at the bottom of the lower pad (23).

6. The mold for molding a temple support according to claim 1, wherein the molding block (7) comprises a riser (25) fixed to an inner face of the slider (9), a first molding projection (26) provided on an inner face of the riser (25), and a second molding projection (27) provided on an inner face of the second molding projection (27);

the molding groove (8) comprises a first accommodating groove (28) arranged at the side part of the upper molding plate (4) and a second accommodating groove (29) connected to the inner side of the first accommodating groove (28).

7. The temple support molding die of claim 6, wherein the riser (25) is fitted into the first receiving groove (28) and the first molding projection (26) and the second molding projection (27) are fitted into the second receiving groove (29) when the molding block (7) is fitted into the molding groove (8);

the inner wall of the first accommodating groove (28) is respectively attached and connected with the upper surface, the front surface, the rear surface and the inner side surface of the vertical plate (25);

the inner wall of the second accommodating groove (29) is respectively attached to the upper surface, the front surface and the rear surface of the first forming boss (26);

and spacing intervals for molding are reserved between the inner wall of the second accommodating groove (29) and the upper surface, the front surface, the rear surface and the inner side surface of the second molding boss (27).

8. The forming mold for the temple support according to claim 6, wherein a positioning block (31) is arranged at the bottom of the first forming boss (26), and the outer side of the positioning block (31) is connected with a vertical plate (25);

the side part of the upper surface of the lower forming plate (6) is provided with a first positioning groove (32) corresponding to the vertical plate (25), and the first positioning groove (32) is positioned on the inner side of the sliding block (9);

a second positioning groove (33) connected to the inner side of the first positioning groove (32) is formed in the upper surface of the lower forming plate (6) corresponding to the positioning block (31), and the first forming boss (26) and the second forming boss (27) are located above the first positioning groove (32) and the second positioning groove (33);

when the molding module (7) is embedded into the molding groove (8), the lower part of the vertical plate (25) is embedded into the first positioning groove (32), and the positioning block (31) is embedded into the second positioning groove (33).

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