CN111099332A

CN111099332A - Glass bottle steering mechanism

Info

Publication number: CN111099332A
Application number: CN201911398772.4A
Authority: CN
Inventors: 上官石林; 戴金球; 程虎
Original assignee: Chongqing Huabinwei Glass Co Ltd
Current assignee: Chongqing Huabinwei Glass Co Ltd
Priority date: 2019-12-30
Filing date: 2019-12-30
Publication date: 2020-05-05
Anticipated expiration: 2039-12-30
Also published as: CN111099332B

Abstract

The invention relates to the technical field of glass production, and discloses a glass bottle steering mechanism which comprises a grooved pulley and a rotating disc driven by a driving piece, wherein a locking disc matched with the grooved pulley is coaxially and fixedly installed on the rotating disc, and a cylindrical pin for pushing the grooved pulley to rotate is arranged at the position of the rotating disc deviating from the circle center; a supporting disk is rotatably connected below the grooved wheel, a plurality of negative pressure holes are formed in the supporting disk along the circumferential direction of the supporting disk, a sealing disk which is rotatably connected with the supporting disk is arranged below the supporting disk, an air hole communicated with the negative pressure holes is formed in the sealing disk, and a negative pressure assembly is communicated with the air hole; the periphery fixedly connected with deflector of supporting disk has seted up feed inlet and discharge gate on the deflector. The glass bottle reversing device is simple in structure, and can reverse glass bottles so as to adapt to steering transportation of the glass bottles.

Description

Glass bottle steering mechanism

Technical Field

The invention relates to the technical field of glass production, in particular to a glass bottle steering mechanism.

Background

Glass bottles are traditional beverage packaging containers in China, and the glass containers still occupy an important position in beverage packaging under the condition that a plurality of packaging materials are introduced into the market.

In the glass production process, need transport the packing box with the glass after the shaping in, generally convey the glass bottle through the conveyer belt now, because the restriction of place size, the conveyer belt can not set up with a sharp mode, then need turn to the conveyer belt to turn to the transportation to the glass bottle. However, the belt is difficult to bend, and therefore the belt cannot be easily turned. In the prior art, in order to achieve the purpose of turning the conveyor belts, an arc-shaped guide groove is arranged between the two conveyor belts to serve as a glass bottle turning mechanism, and the conveyor belts are turned through the guide groove. The guide groove is arranged between the two conveyor belts, so that the glass bottles are not convenient to transport, even the guide groove is blocked, and in order to facilitate the conveyor belts to steer and transport the glass bottles, the steering mechanism is required to be improved.

Disclosure of Invention

The invention aims to provide a glass bottle steering mechanism which is convenient for a conveyor belt to steer and transport glass bottles.

In order to achieve the purpose, the invention provides the following technical scheme: a glass bottle steering mechanism comprises a grooved pulley and a rotating disc driven by a driving part, wherein a locking disc matched with the grooved pulley is coaxially and fixedly installed on the rotating disc, and a cylindrical pin for pushing the grooved pulley to rotate is arranged at the position of the rotating disc deviating from the center of a circle; a supporting disk is rotatably connected below the grooved wheel, a plurality of negative pressure holes are formed in the supporting disk along the circumferential direction of the supporting disk, a sealing disk which is rotatably connected with the supporting disk is arranged below the supporting disk, an air hole communicated with the negative pressure holes is formed in the sealing disk, and a negative pressure assembly is communicated with the air hole; the periphery fixedly connected with deflector of supporting disk has seted up feed inlet and discharge gate on the deflector.

The principle and the beneficial effects of the invention are as follows:

(1) the driving piece drives the rotating disc, the rotating disc drives the locking disc and the cylindrical pin to rotate, the cylindrical pin drives the grooved wheel to rotate, and the grooved wheel axially rotates, so that a circular track can be formed in glass bottle transportation, different steering angles can be adapted, the grooved wheel pushes the glass bottle to the discharge port from the feed port, the purpose of steering the glass bottle is achieved, and the glass bottle can be conveniently steered. The radian of guide way is generally definite, and operating personnel wants to change and turns to the corresponding guide way of angle then need be changed, leads to the cost higher, and the contained angle that only needs to change feed inlet and discharge gate in this scheme then can change the angle that turns to of glass bottle, the cost is reduced.

(2) Because the mutual extrusion of glass bottle during the guide way transmission leads to the glass bottle to extrude from the guide way easily, this scheme adsorbs the glass bottle through negative pressure subassembly, gas pocket and negative pressure pore pair at the in-process that the groove wheel promoted glass bottle to guarantee the stability of glass bottle transportation, reduce the probability that glass bottle and supporting disk break away from, this scheme has overcome above problem through negative pressure subassembly.

(3) In the process of transporting the glass bottles by the grooved pulley, the guide plate limits the glass bottles so as to prevent the glass bottles from being separated from the supporting plate.

Furthermore, both sides of the feed inlet are provided with side plates arranged on the guide plate.

Has the advantages that: the installation curb plate can lead to the glass bottle can be accurate reach the feed inlet.

Further, a conveyor belt is arranged below the side plate.

Has the advantages that: the glass bottles are conveyed by the conveyor belt so as to be convenient for transportation of the glass bottles.

Furthermore, a main gear is coaxially fixed on an output shaft of the driving part, the main gear is meshed with a driven gear, a driving disc is fixed on the driven gear, a connecting rod hinged with a side plate is hinged to the position, deviating from the center of a circle, of the driving disc, and bristles are fixed on one side, far away from the connecting rod, of the side plate.

Has the advantages that: when the driving piece drives the main gear to rotate, the main gear drives the driven gear and the driving disc to move, the driving disc drives the connecting rod and the side plate to move towards the glass bottle in a reciprocating mode, and bristles on the side plate clean the glass bottle.

Further, the negative pressure assembly comprises a negative pressure box and a negative pressure pump communicated with the negative pressure box, and the air pipe is communicated with the negative pressure box through an air pipe.

Has the advantages that: the negative pressure pump pumps negative pressure to the negative pressure box, and the glass bottle is adsorbed through the negative pressure, so that the shaking of the glass bottle is reduced, and the conveying stability of the glass bottle is improved.

Furthermore, a supporting shaft penetrating through the circle center of the grooved wheel is fixed on the supporting plate, a connecting plate is fixed on the supporting shaft, a first permanent magnet is fixed on the connecting plate, a pushing plate is horizontally and slidably connected in a groove of the grooved wheel, an elastic piece abutting against the grooved wheel is fixed on the pushing plate, a second permanent magnet is fixed on the pushing plate, and the magnetic poles of the first permanent magnet and the second permanent magnet are opposite.

Has the advantages that: when the grooved pulley pushes the glass bottle to move to the discharge port, the first permanent magnet is opposite to the second permanent magnet, the first permanent magnet pushes the second permanent magnet under the action of magnetic force, and the second permanent magnet drives the pushing plate to move towards the glass bottle, so that the glass bottle is pushed out from the supporting plate, and the glass bottle is convenient to transport.

Further, the guide plate is a telescopic plate.

Has the advantages that: the position of the feed inlet and the discharge outlet can be adjusted through the stretching of the telescopic plate, and the position of the feed inlet and the position of the discharge outlet are convenient to adjust.

Furthermore, the gear ratio of the master gear to the slave gear is 1: 5-1: 8.

Has the advantages that: the gear ratio of the main gear to the driven gear is 1: 5-1: 8, the rotation speed of the main gear is high, the rotation speed of the driven gear is low, the rotation speed of the driving disc is reduced, the driving disc drives the connecting rod to move slowly, and strong impact between the side plate and the glass bottle due to the fact that the side plate moves too fast is avoided.

Further, a protective layer is mounted on the side wall of the guide plate.

Has the advantages that: the glass bottle is protected by the protective layer, so that the glass bottle is prevented from rubbing the guide plate, and the glass bottle is prevented from being damaged.

Further, still include the workstation, the negative pressure pump is installed on the workstation.

Has the advantages that: the negative pressure pump is mounted on the work table so as to facilitate movement of the negative pressure pump.

Drawings

FIG. 1 is an isometric view of a carafe steering mechanism in accordance with a first embodiment of the present invention;

FIG. 2 is a front view of a carafe steering mechanism in accordance with a first embodiment of the present invention;

FIG. 3 is a top view of a carafe steering mechanism in accordance with one embodiment of the present invention;

FIG. 4 is a cross-sectional view taken along line E-E of FIG. 3;

FIG. 5 is a cross-sectional view of a vial diverting mechanism according to a second embodiment of the present invention.

Detailed Description

The following is further detailed by way of specific embodiments:

reference numerals in the drawings of the specification include: the device comprises a workbench 1, a single-phase motor 2, a main gear 21, a rotating disc 22, a cylindrical pin 23, a locking disc 24, a driven gear 25, a driving disc 26, a connecting rod 27, a guide plate 3, a discharge port 31, a feed port 32, a grooved wheel 4, a groove 41, a pushing groove 42, a pushing plate 43, a spring 44, a second permanent magnet 45, a side plate 5, a conveyor belt 6, a driving motor 61, a rack 62, a negative pressure box 7, a negative pressure pipe 71, a negative pressure pump 72, a supporting disc 8, a negative pressure hole 81, a sealing disc 9, an air hole 91, a supporting shaft 10, a connecting plate 101 and a first permanent magnet 102.

The first embodiment is as follows:

as shown in fig. 1 and fig. 2, a glass bottle steering mechanism comprises a workbench 1, a frame 62 is mounted on the left side of the workbench 1 through a fastening bolt, a conveyor belt 6 driven by a driving motor 61 is mounted on the frame 62, and the driving motor 61 is mounted on the frame 62 through a fastening bolt. The driving piece is installed on the right side of the workbench 1, the driving piece is a single-phase motor 2 in the embodiment, the single-phase motor 2 is fixed on the workbench 1 through a fastening bolt, a rotating disc 22 is coaxially welded and fixed on an output shaft of the single-phase motor 2, a locking disc 24 is coaxially fixed on the rotating disc 22 through a fastening bolt, and a cylindrical pin 23 is welded and fixed at the position deviating from the circle center of the rotating disc 22.

As shown in fig. 4, a negative pressure assembly is arranged on the workbench 1, and in the present embodiment, the negative pressure assembly includes a negative pressure pump 72 fixed on the workbench 1 through a fastening bolt, and the negative pressure pump 72 is communicated with the negative pressure tank 7 through an air pipe.

A support column is fixedly welded on the workbench 1, a sealing disc 9 is coaxially fixedly welded on the support column, a plurality of air holes 91 are formed in the circumferential direction of the sealing disc 9, and the air holes 91 are communicated with the negative pressure box 7 through the negative pressure pipe 71. A supporting disk 8 rotatably connected with the supporting column is arranged above the sealing disk 9, a plurality of negative pressure holes 81 are formed in the supporting disk 8, part of the negative pressure holes 81 are sealed by the sealing disk 9, and part of the negative pressure holes 81 in the sealing disk 9 are communicated with the air holes 91.

As shown in fig. 3, a sheave 4 coaxially and rotatably connected with the support column is arranged above the support plate 8, a plurality of grooves 41 with arc-shaped cross sections and a plurality of pushing grooves 42 are circumferentially arranged on the sheave 4, the pushing grooves 42 are matched with the cylindrical pin 23, and the grooves 41 and the locking disk 24 are arranged. When the single-phase motor 2 drives the rotating disc 22 to rotate, the cylindrical pin 23 extends into the pushing groove 42 to push the groove 42 to rotate, and when the locking disc 24 rotates in the groove 41, the sheave 4 stops rotating.

The supporting disc 8 is fixed with the guide plate 3 located on the periphery of the grooved pulley 4 through a fastening bolt, the longitudinal section of the guide plate 3 is arc-shaped, the inner side of the guide plate 3 is fixedly bonded with a protective layer, the protective layer is a sponge layer in the embodiment, three and three guide plates 3 of the guide plate 3 are all telescopic plates, namely the guide plates 3 can be telescopic to change the length of the guide plates, and a feed port 32 and a discharge port 31 are formed between every two adjacent guide plates 3. Two side plates 5 positioned above the conveyor belt 6 are arranged on two sides of the feed port 32, one side plate 5 is hinged with the guide plate 3, the other side plate 5 is fixedly connected with the guide plate 3, and bristles are fixedly bonded on one side of the side plate 5 facing the conveyor belt 6. Referring to fig. 2, a main gear 21 is coaxially welded and fixed on an output shaft of the single-phase motor 2, the main gear 21 is engaged with a driven gear 25 rotationally connected with the worktable 1, and the gear ratio of the main gear 21 to the driven gear 25 is 1: 5. A fulcrum shaft is coaxially welded and fixed to the driven gear 25, a driving disc 26 is coaxially welded and fixed to the fulcrum shaft, a connecting rod 27 is hinged to the driving disc 26, and the connecting rod 27 is hinged to the side plate 5 close to the driven gear 25.

The specific implementation process is as follows:

as shown in figure 3, when the glass bottles are conveyed to the conveyor 6, the conveyor 6 is driven by the driving motor 61 to work, the glass bottles are conveyed to the supporting plate 8 by the conveyor 6 through the side plate 5 and the feeding port 32 and are positioned in one groove 41 of the grooved pulley 4, the grooved pulley 4 pushes the glass bottles to be diverted to the discharging port 31 and conveyed to other conveying mechanisms, and therefore the rotating and conveying of the glass bottles can be achieved.

Specifically, the method comprises the following steps: during the conveying process of the glass bottles on the conveyor belt 6, the single-phase motor 2 drives the main gear 21, the main gear 21 drives the driven gear 25 and the driving disc 26 to rotate, the driving disc 26 drives the connecting rod 27 and the side plate 5 to reciprocate, and the brush on the side plate 5 cleans the surfaces of the glass bottles.

When the conveyor belt 6 conveys the glass bottles onto the supporting disc 8 and is positioned in the groove 41, the single-phase motor 2 drives the cylindrical pin 23 and the locking disc 24 through the rotating disc 22, the locking disc 24 rotates in the groove 41, the grooved pulley 4 stops rotating, the cylindrical pin 23 extends into the pushing groove 42, the cylindrical pin 23 pushes the groove 42 to rotate clockwise, and thus the grooved pulley 4 pushes the glass bottles to move to the discharge hole 31. When the contained angle of feed inlet 32 and discharge gate 31 was 90, then the glass bottle turned to 90, in this scheme, can adjust the contained angle of feed inlet 32 and discharge gate 31 through the flexible of deflector 3 to adjust the angle of turning to of glass bottle. Of course, the position of the closing disk 9 is also adjusted to ensure that the air holes 91 on the closing disk 9 are communicated with the negative pressure holes 81, and the closing disk 9 closes part of the negative pressure holes 81 (as shown in fig. 4).

As shown in figure 4, when the glass bottle passes through the feed inlet 32 and is positioned on the supporting plate 8, the negative pressure pump 72 pumps negative pressure to the negative pressure box 7, and the negative pressure box 7 generates negative pressure through the negative pressure pipe 71, the air hole 91 and the negative pressure hole 81 to adsorb the bottom of the glass bottle, so that the stable conveying of the glass bottle is ensured. When the glass bottle is positioned at the discharge port 31, the negative pressure hole 81 is blocked by the sealing disc 9, and the glass bottle is not adsorbed by the negative pressure at the moment, and is sent to other conveying mechanisms.

Example two:

the difference between the second embodiment and the first embodiment is that, as shown in fig. 5, a connecting plate 101 is coaxially welded and fixed on the supporting shaft 10, the connecting plate 101 is located at the discharging port 31, a first permanent magnet 102 is fixed on the bottom surface of the left side of the connecting plate 101 through a fastening bolt, a plurality of pushing plates 43 are arranged on the sheave 4 along the circumferential direction thereof, the pushing plates 43 are respectively located in the grooves 41, the pushing plates 43 are horizontally slidably connected with the sheave 4, an elastic member is arranged between the pushing plates 43 and the sheave 4, the elastic member in this embodiment is a spring 44, two ends of the spring 44 are respectively welded and fixed on the sheave 4 and the pushing plates 43, a second permanent magnet 45 is fixed on the pushing plates 43 through a fastening bolt, and the opposite magnetic poles of the first permanent magnet 102 and the second.

The specific implementation process is as follows:

when the grooved pulley 4 pushes the glass bottles to move to the discharge port 31, the first permanent magnet 102 and the second permanent magnet 45 are opposite, the first permanent magnet 102 pushes the second permanent magnet 45 to slide, the second permanent magnet 45 drives the pushing plate 43, and the pushing plate 43 pushes the glass bottles out, so that the glass bottles are conveniently transported to other conveying mechanisms. When the first permanent magnet 102 and the second permanent magnet 45 are separated, the push plate 43 is returned by the spring 44.

The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, it is possible to make several variations and modifications without departing from the concept of the present invention, and these should be considered as the protection scope of the present invention, which will not affect the effect of the implementation of the present invention and the utility of the patent. The techniques, shapes, and structural parts, which are omitted from the description of the present invention, are all known techniques.

Claims

1. Glass bottle steering mechanism, its characterized in that: the device comprises a grooved wheel and a rotating disc driven by a driving part, wherein a locking disc matched with the grooved wheel is coaxially and fixedly installed on the rotating disc, and a cylindrical pin for pushing the grooved wheel to rotate is arranged at the position of the rotating disc deviating from the center of a circle;

a supporting disk is rotatably connected below the grooved wheel, a plurality of negative pressure holes are formed in the supporting disk along the circumferential direction of the supporting disk, a sealing disk which is rotatably connected with the supporting disk is arranged below the supporting disk, an air hole communicated with the negative pressure holes is formed in the sealing disk, and a negative pressure assembly is communicated with the air hole;

the periphery fixedly connected with deflector of supporting disk has seted up feed inlet and discharge gate on the deflector.

2. The vial diverting mechanism according to claim 1, wherein: and side plates arranged on the guide plate are arranged on two sides of the feed inlet.

3. The vial diverting mechanism according to claim 2, wherein: and a conveyor belt is arranged below the side plate.

4. The vial diverting mechanism according to claim 2, wherein: a main gear is coaxially fixed on an output shaft of the driving part, the main gear is meshed with a driven gear, a driving disc is fixed on the driven gear, a connecting rod hinged with a side plate is hinged to the position, deviating from the center of a circle, of the driving disc, and bristles are fixed on one side, far away from the connecting rod, of the side plate.

5. The vial diverting mechanism according to claim 1, wherein: the negative pressure assembly comprises a negative pressure box and a negative pressure pump communicated with the negative pressure box, and the air pipe is communicated with the negative pressure box through an air pipe.

6. The vial diverting mechanism according to claim 1, wherein: the supporting disc is fixedly provided with a supporting shaft penetrating through the center of the grooved pulley, the supporting shaft is fixedly provided with a connecting plate, a first permanent magnet is fixedly arranged on the connecting plate, a pushing plate is horizontally and slidably connected in a groove of the grooved pulley, an elastic piece abutting against the grooved pulley is fixedly arranged on the pushing plate, a second permanent magnet is fixedly arranged on the pushing plate, and the magnetic pole of one surface of the first permanent magnet opposite to the magnetic pole of the other surface of the first permanent magnet opposite to the magnetic pole of the second permanent magnet.

7. A vial diverting mechanism according to any of claims 1 to 6, characterized in that: the guide plate is a telescopic plate.

8. The vial diverting mechanism according to claim 4, wherein: the gear ratio of the master gear to the slave gear is 1: 5-1: 8.

9. The vial diverting mechanism according to claim 1, wherein: and a protective layer is arranged on the side wall of the guide plate.

10. The carafe steering mechanism as in claim 9, wherein: the vacuum pump is arranged on the workbench.