CN218202524U - Moulding-die gas cap structure for glass cup production - Google Patents

Abstract

The utility model discloses a moulding-die gas cap structure for glass cup production, including carousel component, mould and pneumatic telescoping cylinder, the mould includes right mould and left mould, one side of right mould and the left mould all is equipped with the ejector pin mounting panel, the back shaft is installed in the center of ejector pin mounting panel on one side of the left mould, the back shaft periphery cover is equipped with left locking structure and right locking structure, the inside of left locking structure and right locking structure all is connected with the locking post, two the locking post respectively with two ejector pin mounting panels interconnect; through pneumatic telescoping cylinder, locking post and left and right locking structure cooperation use, after glass accomplished suppression and cooling step, the mould was carried to pneumatic telescoping cylinder top, and the ejector pin can be pushed to pneumatic telescoping cylinder's output, and the ejector pin drives left and right locking structure and rotates, and its outside helicla flute can opposite promotion locking post move when left and right rotation, avoids operating personnel to open the mould manually, provides the degree of automation of glass cup production process.

Description

Moulding-die gas cap structure for glass cup production

Technical Field

The utility model relates to a glass cup production facility technical field specifically is a glass cup production is with moulding-die gas cap structure.

Background

The glass cup manufacturing method is generally divided into a blowing method and a pressing method, when the glass cup is manufactured by adopting the pressing method, molten glass is placed in a lower die, then the molten glass is extruded into the lower die by adopting an upper die, the molten glass can form a specific shape under the action of pressure, the qualitative and external outline of the glass cup produced by adopting the method in the lower die are the same as the outline of a cavity in the lower die, and an operator needs to take the glass cup out of the lower die by adopting an ejection structure;

when the outer wall of the glass cup is provided with the pattern structure, after the outer wall of the glass cup is attached to the inner cavity of the lower die, the pattern of the glass cup can be damaged by adopting a traditional direct-acting ejection structure, the two half lower dies are required to be used for production at the moment, the two half lower dies are required to be manually opened by an operator after the die pressing is completed, the operation time is consumed during the operation, and the automatic production degree of the glass cup is reduced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a moulding-die gas cap structure is used in glass cup production to solve the problem that proposes in the above-mentioned background art.

The utility model provides a following technical scheme: a pressing die gas cap structure for glass cup production comprises a turntable component, dies and a pneumatic telescopic cylinder, wherein the plurality of dies are arranged on the periphery of the top of the turntable component, and the pneumatic telescopic cylinder is arranged on one side of the turntable component;

preferably, the mould includes right mould and left mould, the right side mould with one side of left side mould all is equipped with the ejector pin mounting panel, the central authorities of left side mould one side ejector pin mounting panel install the back shaft, two back shaft periphery cover is equipped with left locking structure and right locking structure between the ejector pin mounting panel, the inside of left side locking structure and right locking structure all is connected with the boss, one side of boss is equipped with the locking post, two the locking post is respectively with two ejector pin mounting panel interconnect.

Preferably, the carousel component includes pillar, support frame and carousel, and the outside cover of pillar is equipped with the carousel, and the periphery of carousel below pillar is equipped with the support frame, and the top of support frame and the bottom interconnect of carousel.

Preferably, the base is installed to the bottom of pneumatic telescoping cylinder, and the output of pneumatic telescoping cylinder is installed the top mould structure, and one side that the carousel component was kept away from to the base is equipped with the micro-gap switch support, and the micro-gap switch is installed to the tip of micro-gap switch support.

Preferably, one side of the right die is provided with a right sleeve, the left die is provided with a left sleeve on the side corresponding to the right sleeve, a rotating shaft is arranged inside the right sleeve and the left sleeve in a penetrating mode, and a fixing plate is arranged at the bottom end of the rotating shaft.

Preferably, one end of the supporting shaft penetrates through the inner part of the ejector rod mounting plate to be connected with an ejector rod, and the ejector rod is located above the top die structure.

Preferably, a gear box is installed inside the support column, a motor is installed on one side of the gear box, a gear is installed on the other side of the gear box, and the gear is meshed with the inner periphery of the rotary table.

The beneficial effects of the utility model are that:

the utility model discloses a pneumatic telescoping cylinder, locking post and left and right locking structure cooperation are used, glass accomplishes suppression and cooling step back, and the mould is carried to pneumatic telescoping cylinder top, and the ejector pin can be pushed up to the output of pneumatic telescoping cylinder, and the ejector pin drives left and right locking structure and rotates, and its outside helicla flute can opposite promotion locking post move when left and right rotation, and then makes the left and right sides of mould open, avoids operating personnel to manually open the mould, provides the degree of automation of glass cup production process.

Drawings

Fig. 1 is a schematic side view of the present invention;

fig. 2 is a schematic top view of the mold of the present invention;

fig. 3 is an enlarged schematic view of a part a of the present invention;

fig. 4 is a schematic top view of the present invention.

In the figure: 1. a turntable member; 101. a pillar; 102. a support frame; 103. a turntable; 2. a mold; 201. a right die; 202. a left die; 3. a top rod; 301. a support shaft; 302. a left locking structure; 303. a right locking structure; 4. a pneumatic telescopic cylinder; 401. a top mold structure; 402. a base; 403. a microswitch bracket; 5. a microswitch; 6. a right sleeve; 7. a left sleeve; 8. a fixing plate; 801. a rotating shaft; 9. a mandril mounting plate; 10. a locking post; 1001. a boss; 11. a gear case; 1101. a motor; 1102. a gear.

Detailed Description

In the description of the present invention, it should be noted that the terms "upper", "lower", "inner", "outer", "front end", "rear end", "both ends", "one end", "the other end" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element to which the reference is made must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "disposed," "connected," and the like are to be construed broadly, and for example, "connected" may be either fixedly connected or detachably connected, or integrally connected; 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 invention can be understood as a specific case by those skilled in the art.

The technical solution of the present invention will be further described in detail with reference to the drawings and specific embodiments.

The pressing die gas cap structure for producing the glass cup comprises a turntable member 1, dies 2 and a pneumatic telescopic cylinder 4, wherein the dies 2 are installed on the periphery of the top of the turntable member 1, and the pneumatic telescopic cylinder 4 is installed on one side of the turntable member 1;

the die 2 comprises a right die 201 and a left die 202, one side of the right die 201 and one side of the left die 202 are both provided with ejector rod mounting plates 9, the center of the ejector rod mounting plate 9 on one side of the left die 202 is provided with a supporting shaft 301, the periphery of the supporting shaft 301 between the two ejector rod mounting plates 9 is sleeved with a left locking structure 302 and a right locking structure 303, the insides of the left locking structure 302 and the right locking structure 303 are both connected with a boss 1001, one side of the boss 1001 is provided with locking columns 10, and the two locking columns 10 are respectively connected with the two ejector rod mounting plates 9;

one end of the supporting shaft 301 penetrates through the inside of the ejector rod mounting plate 9 to be connected with an ejector rod 3, and the ejector rod 3 is located above the top die structure 401.

Specifically, the turntable member 1 drives the plurality of dies 2 to rotate, the dies 2 rotate to positions corresponding to the pneumatic telescopic cylinder 4, the telescopic end of the pneumatic telescopic cylinder 4 is ejected upwards, the ejector rod 3 is ejected by the pneumatic telescopic cylinder 4, the ejector rod 3 drives the supporting shaft 301 to rotate, the supporting shaft 301 rotates to enable the left locking structure 302 and the right locking structure 303, the boss 1001 is pushed to move transversely left and right when the left locking structure 302 and the right locking structure 303 rotate, the boss 1001 and the locking columns 10 are welded with each other, and then the two locking columns 10 drive the two ejector rod mounting plates 9 to open;

wherein, the 4 models of pneumatic telescoping cylinder are SU40X600, pneumatic telescoping cylinder 4 mainly comprises flexible post and cylinder, pneumatic telescoping cylinder 4 connects through interface and outside gas circuit, aerify and deflate through control and make pneumatic telescoping cylinder 4 stretch out and draw back, right side mould 201 and left mould 202 and ejector pin mounting panel 9 weld each other, adopt bearing structure to connect between back shaft 301 and one of them ejector pin mounting panel 9, spiral groove has been seted up respectively to left locking structure 302 and right locking structure 303 outer wall, and the outside spiral groove direction of rotation of left locking structure 302 and right locking structure 303 is opposite, boss 1001 slidable mounting is in spiral groove's inside.

Further, the turntable member 1 comprises a support 101, a support frame 102 and a turntable 103, wherein the turntable 103 is sleeved outside the support 101, the support frame 102 is arranged on the periphery of the support 101 below the turntable 103, and the top of the support frame 102 is connected with the bottom of the turntable 103;

a gear case 11 is installed inside the column 101, a motor 1101 is installed on one side of the gear case 11, a gear 1102 is installed on the other side of the gear case 11, and the gear 1102 is engaged with the inner circumference of the turntable 103.

Specifically, pillar 101 is a cylindrical structure, a cavity is formed in the top of pillar 101 to provide an installation space for gear box 11, gear box 11 is installed inside pillar 101 by adopting a bolt structure, gear box 11 is a gear reduction case, gear box 11 is installed through an internal gear width and an output end of motor 1101 by a key pin structure, an output shaft of motor 1101 drives a gear width to be meshed, an output shaft of gear box 11 is driven to rotate through gear width meshing, an output end of gear box 11 drives gear 1102 to rotate, gear 1102 can be meshed with transmission turntable 103 when rotating, a transmission gear structure is arranged on the inner periphery of turntable 103, turntable 103 is further driven to rotate, a bearing structure is arranged between the bottom of turntable 103 and support frame 102, specifically, a plane bearing is arranged on the top of support frame 102, ball bearings are sleeved on the inner periphery and outer periphery of support frame 102, motor 1101 is a servo motor, and a plc control system is adopted by the control system.

Further, a base 402 is installed at the bottom of the pneumatic telescopic cylinder 4, a top die structure 401 is installed at the output end of the pneumatic telescopic cylinder 4, a micro switch bracket 403 is arranged on one side of the base 402 far away from the turntable member 1, and a micro switch 5 is installed at the end of the micro switch bracket 403.

Specifically, base 402 and pneumatic telescoping cylinder 4 bottom adopt bolt construction fixed, top die structure 401 adopts bolt construction and pneumatic telescoping cylinder 4's flexible end fixed mounting, micro-gap switch support 403 is L type structure, micro-gap switch 5 installs in top die structure 401's top, last the last extrusion micro-gap switch 5 that shifts up after pneumatic telescoping cylinder 4 work is accomplished, micro-gap switch 5 can feedback signal give control system, make pneumatic telescoping cylinder 4 contract, control system can control motor 1101 drive carousel 103 carry out the rotation of fixed angle simultaneously.

Furthermore, a right sleeve 6 is arranged on one side of the right die 201, a left sleeve 7 is arranged on the side, corresponding to the right sleeve 6, of the left die 202, a rotating shaft 801 penetrates through the insides of the right sleeve 6 and the left sleeve 7, and a fixing plate 8 is arranged at the bottom end of the rotating shaft 801.

Specifically, right sleeve 6, left sleeve 7 and pivot 801 constitute hinge structure, and wherein the top welding of that pivot 801 has one to shelter from the flange for when preventing pneumatic telescoping cylinder 4 top from moving ejector pin 3, mould 2 upwards slides from pivot 801, increases the stability of device, and fixed plate 8 is mould 2's bottom fixed knot structure, adopts bolt structure to install fixed plate 8 at the top of carousel 103, can install mould 2.

The working principle is as follows: carousel component 1 drives a plurality of moulds 2 and rotates, mould 2 is rotatory to the corresponding position department of pneumatic telescoping cylinder 4, the flexible end of pneumatic telescoping cylinder 4 is upwards ejecting, ejector pin 3 is moved in the top of pneumatic telescoping cylinder 4, ejector pin 3 drives back shaft 301 and rotates, back shaft 301 is rotatory can make left locking structure 302 and right locking structure 303, when left locking structure 302 and right locking structure 303 are rotatory, left locking structure 302 and right locking structure 303 outer wall are equipped with the spiral groove opposite in direction of rotation and can push the boss and control the sideslip, and then two 1001 locking posts can drive two ejector pin mounting panels 9 and open.

Claims (6)

1. A pressing die gas cap structure for glass cup production comprises a turntable component (1), dies (2) and a pneumatic telescopic cylinder (4), wherein the plurality of dies (2) are installed on the periphery of the top of the turntable component (1), and the pneumatic telescopic cylinder (4) is installed on one side of the turntable component (1); the method is characterized in that: the mould (2) comprises a right mould (201) and a left mould (202);

right side mould (201) with one side of left side mould (202) all is equipped with ejector pin mounting panel (9), back shaft (301), two are installed to the central authorities of left side mould (202) one side ejector pin mounting panel (9) back shaft (301) periphery cover is equipped with left locking structure (302) and right locking structure (303) between ejector pin mounting panel (9), the inside of left side locking structure (302) and right locking structure (303) all is connected with boss (1001), one side of boss (1001) is equipped with locking post (10), two locking post (10) respectively with two ejector pin mounting panel (9) interconnect.

2. A press mold holder-on structure for producing a glass cup as set forth in claim 1, wherein: the turntable component (1) comprises a support column (101), a support frame (102) and a turntable (103), the turntable (103) is sleeved outside the support column (101), the support frame (102) is arranged on the periphery of the support column (101) below the turntable (103), and the top of the support frame (102) is connected with the bottom of the turntable (103).

3. A press mold holder-on structure for producing a glass cup as set forth in claim 1, wherein: the bottom of pneumatic telescoping cylinder (4) is installed base (402), and top mould structure (401) are installed to the output of pneumatic telescoping cylinder (4), and one side that carousel component (1) was kept away from in base (402) is equipped with micro-gap switch support (403), and micro-gap switch (5) are installed to the tip of micro-gap switch support (403).

4. A press mold holder-on structure for producing a glass cup as set forth in claim 1, wherein: one side of right mould (201) is equipped with right sleeve (6), and left mould (202) is equipped with left sleeve (7) with right sleeve (6) corresponding side, and the inside of right sleeve (6) and left sleeve (7) is run through and is installed pivot (801), and the bottom of pivot (801) is equipped with fixed plate (8).

5. A press mold holder-on structure for producing a glass cup as set forth in claim 1 or 3, wherein: the one end of back shaft (301) runs through the internal connection of ejector pin mounting panel (9) and has ejector pin (3), and ejector pin (3) are located the top of top mould structure (401).

6. The press mold gas cap structure for glass cup production according to claim 2, characterized in that: a gear box (11) is installed inside the strut (101), a motor (1101) is installed on one side of the gear box (11), a gear (1102) is installed on the other side of the gear box (11), and the gear (1102) is meshed with the inner periphery of the rotary table (103).

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