CN216967325U - Fine material gold wire glass bottle processing device - Google Patents

Abstract

The utility model relates to the field of glass bottle processing, and particularly discloses a processing device for a fine material spun gold glass bottle, which comprises a workbench and a glass bottle, wherein the workbench is horizontally arranged, the glass bottle is vertically arranged, a polishing component, a transmission component and a cleaning component are sequentially arranged in the workbench from left to right, the polishing component is positioned right below a polishing hole and is used for polishing the bottom of the glass bottle, the transmission component is matched with the polishing component to drive the polishing component to overturn a polishing surface on the polishing component in the rotating process, and the cleaning component is used for cleaning debris attached to the overturned polishing surface; after the dish of polishing was polished at the bottom of the bottle, drive assembly ordered about the dish of polishing and removed clearance position department from the position of polishing to in-process upset in the motion makes its face of polishing from setting up the upset to position down, utilizes the clearance subassembly alright afterwards to clear up the dish of polishing, because the setting down of face of polishing, the piece just can fall by oneself, avoids the piece to polish at the bottom of the follow-up bottle of attached influence on the face of polishing.

Description

Fine material gold wire glass bottle processing device

Technical Field

The utility model relates to the field of glass bottle processing, in particular to a device for processing a fine material gold wire glass bottle.

Background

The production equipment of the fine material golden wire glass bottle is used for producing colored glass, the glass bottle is a traditional beverage packaging container in China, the glass is also a historical packaging material, under the condition that a plurality of packaging materials are introduced into the market, the glass container still occupies an important position in beverage packaging, the packaging characteristic that the glass container cannot be replaced by other packaging materials is not distinguished, the annual recovery amount of the glass bottle recovered glass bottle is increased, but the recovery amount is huge and immeasurable.

When polishing at the bottom of present to the bottle of glass bottle, because the glass bottle is placed on the dish of polishing mostly, the piece that the in-process of polishing produced just can be attached to the dish of polishing, and then the piece just can influence the dish of polishing and to the polishing at the bottom of follow-up glass bottle.

SUMMERY OF THE UTILITY MODEL

The utility model provides a processing device for a fine gold wire glass bottle, which solves the technical problem that chips are attached to a polishing disc to affect subsequent polishing of the bottom of the glass bottle in the related technology.

According to one aspect of the utility model, the processing device for the fine material golden silk glass bottle comprises a workbench and glass bottles, wherein the workbench is horizontally arranged, the glass bottles are vertically arranged, polishing holes are formed in the upper surface of the workbench, the bottoms of the glass bottles are placed in the polishing holes, clamps are arranged on two sides of the polishing holes, a polishing component, a transmission component and a cleaning component are sequentially arranged in the workbench from left to right, the polishing component is located right below the polishing holes and used for polishing the bottoms of the glass bottles, the transmission component is matched with the polishing component to drive the polishing component to overturn a polishing surface on the polishing component in the rotating process, and the cleaning component is used for cleaning chips attached to the polishing surface after overturning.

Further, the method comprises the following steps: the grinding assembly comprises a grinding disc and a first driving shaft which is vertically arranged, one end of the first driving shaft is fixedly connected to the grinding disc, and the diameter of the grinding disc is larger than the diameter of the bottom of the glass bottle.

Further, the method comprises the following steps: the transmission assembly comprises a second driving shaft, a driven part and a driving part, the axial direction of the second driving shaft is consistent with the axial direction of the first driving shaft, the transmission shaft is installed at the upper end of the second driving shaft, the axis of the transmission shaft is perpendicular to the axis of the second driving shaft, one end of the transmission shaft is fixedly connected to the polishing assembly, the other end of the transmission shaft is rotatably connected to the second driving shaft, the driven part is matched with the driving part, and the transmission shaft and the polishing assembly rotate around the second driving shaft in the horizontal rotating process.

Further, the method comprises the following steps: the driving piece is installed to the one end that first drive shaft kept away from the mill dish, and the one end fixed connection driving piece that the second drive shaft was kept away from to the transmission shaft.

Further: the connection of the transmission shaft and the driving piece is the gravity center of the grinding assembly.

Further: the polishing assembly is provided with a plurality of groups and is distributed around the second driving shaft in the circumferential direction at equal intervals.

Further: the driving part comprises a helical gear, the helical gear is arranged on the transmission shaft, the axis of the transmission shaft is collinear with the axis of the transmission shaft, the driven part comprises a helical gear disc, the helical gear disc is arranged on the inner wall of the workbench, the helical gear disc is meshed with the helical gear, and the axis of the helical gear disc is collinear with the axis of the second driving shaft.

Further: the clearance subassembly includes third drive shaft and brush, and the third drive shaft is installed in one side of second drive shaft, and the axis of third drive shaft is mutually perpendicular with the axis of second drive shaft, and the brush is installed in the one end of third drive shaft, and the third drive shaft orders about the reciprocal horizontal migration of brush.

Further: the cleaning assembly further comprises a dust collection box, and the dust collection box is inserted into the workbench.

Further: the horizontal height distance between the transmission shaft and the brush is equal to the distance between the transmission shaft and the grinding surface on the grinding disc.

The utility model has the beneficial effects that: after the dish of polishing was polished at the bottom of the bottle, transmission assembly ordered about the dish of polishing and removed clearance position department from the position of polishing to in-process upset in the motion makes its face of polishing set up the upset from up to the position down, utilizes clearance subassembly alright afterwards to clear up the dish of polishing, because the face of polishing sets up down, the piece just can fall by oneself, avoids the piece to polish at the bottom of the subsequent bottle of the adnexed influence on the face of polishing.

Drawings

FIG. 1 is a schematic view of the internal structure of the present invention;

FIG. 2 is an enlarged view of the utility model at A;

FIG. 3 is a schematic view of the brush structure of the present invention;

in the figure: 100. a work table; 110. a clamp; 200. polishing the assembly; 210. grinding disc; 220. a first drive shaft; 300. a transmission assembly; 310. a second drive shaft; 320. a drive shaft; 330. a driving member; 331. a helical gear; 340. a driven member; 341. an inclined fluted disc; 400. cleaning the assembly; 410. a brush; 420. a third drive shaft; 430. a dust collection box; 500. and (4) a glass bottle.

Detailed Description

The subject matter described herein will now be discussed with reference to example embodiments. It should be understood that these embodiments are discussed only to enable those skilled in the art to better understand and thereby implement the subject matter described herein, and are not intended to limit the scope, applicability, or examples set forth in the claims. Changes may be made in the function and arrangement of elements discussed without departing from the scope of the disclosure. Various examples may omit, substitute, or add various procedures or components as needed. In addition, features described with respect to some examples may also be combined in other examples.

Example one

As shown in fig. 1-3, a fine material spun gold glass bottle processing device comprises a workbench 100 and glass bottles 500, wherein the workbench 100 is horizontally arranged, the glass bottles 500 are vertically arranged, a polishing hole is formed in the upper table surface of the workbench 100, the bottoms of the glass bottles 500 are placed inside the polishing hole, clamps 110 are installed on two sides of the polishing hole, a polishing assembly 200, a transmission assembly 300 and a cleaning assembly 400 are sequentially installed inside the workbench 100 from left to right, the polishing assembly 200 is located right below the polishing hole, the polishing assembly 200 is used for polishing the bottoms of the glass bottles 500, the transmission assembly 300 is matched with the polishing assembly 200, the polishing assembly 200 is driven to rotate, the polishing surface on the polishing surface is overturned in the rotating process, and the cleaning assembly 400 is used for cleaning chips attached to the overturned polishing surface.

It should be added that the clamp 110 is composed of a clamping plate and a spring, and the glass bottle is clamped by the elastic force provided by the spring to the clamping plate.

Further: the grinding assembly 200 includes a grinding disc 210 and a vertically arranged first driving shaft 220, one end of the first driving shaft 220 is fixedly connected to the grinding disc 210, and the diameter of the grinding disc 210 is larger than the bottom diameter of the glass bottle 500.

Further: the transmission assembly 300 includes a second driving shaft 310, a driven member 340 and a driving member 330, wherein the axial direction of the second driving shaft 310 is consistent with the axial direction of the first driving shaft 220, the upper end of the second driving shaft 310 is provided with a transmission shaft 320, the axial line of the transmission shaft 320 is perpendicular to the axial line of the second driving shaft 310, one end of the transmission shaft 320 is fixedly connected to the polishing assembly 200, the other end of the transmission shaft 320 is rotatably connected to the second driving shaft 310, and the driven member 340 is matched with the driving member 330 and used for driving the transmission shaft 320 and the polishing assembly 200 to rotate around the second driving shaft 310 in the horizontal rotation process.

Further: the end of the first driving shaft 220 away from the polishing disc 210 is provided with a driving member, and the end of the transmission shaft 320 away from the second driving shaft 310 is fixedly connected with the driving member.

Further: the connection of the drive shaft 320 and the drive member is at the center of gravity of the sanding assembly 200.

Further: the sanding assembly 200 is provided in a plurality of groups and is equally spaced around the circumference of the second drive shaft 310.

Further: the driving member 330 includes a bevel gear 331, the bevel gear 331 is mounted on the transmission shaft 320, an axis of the transmission shaft 320 is collinear with an axis of the transmission shaft 320, the driven member 340 includes a bevel gear disc 341, the bevel gear disc 341 is mounted on an inner wall of the working table 100, the bevel gear disc 341 is engaged with the bevel gear 331, and an axis of the bevel gear disc 341 is collinear with an axis of the second driving shaft 310.

It should be added that two sets of gear teeth are arranged on the helical gear disk 341, the two sets of gear teeth respectively correspond to the polishing position and the cleaning position of the polishing assembly 200 (the polishing position is the position of the polishing disk 210 for polishing the bottom of the glass bottle 500, the cleaning position corresponds to the polishing position, and the two sets of gear teeth are symmetrically arranged along the second driving shaft 310), when the helical gear 331 performs meshing motion on the gear teeth corresponding to the polishing position, the polishing surface on the polishing disk 210 is adjusted upwards, and when the polishing disk 210 polishes the bottom of the bottle, the gear teeth can also limit the polishing assembly 200; when the bevel gear 331 is engaged with the corresponding gear teeth at the cleaning position, the bevel gear is used to adjust the polishing surface of the polishing disk 210 downward, and after the polishing surface is leveled, the polishing surface is cleaned by the reciprocating motion of the brush 410.

Further: the cleaning assembly 400 includes a third driving shaft 420 and a brush 410, the third driving shaft 420 is installed at one side of the second driving shaft 310, an axis of the third driving shaft 420 is perpendicular to an axis of the second driving shaft 310, the brush 410 is installed at one end of the third driving shaft 420, and the third driving shaft 420 drives the brush 410 to reciprocate and move horizontally.

It should be added that driving members are mounted at one end of each of the first driving shaft 220, the second driving shaft 310 and the third driving shaft 420, the driving members on the first driving shaft 220 and the second driving shaft 310 may be driving devices such as a motor and a rotary cylinder, and the driving members on the third driving shaft 420 may be linear driving devices such as a cylinder and an electric telescopic rod.

Further: the cleaning assembly 400 further includes a dust collection box 430, and the dust collection box 430 is inserted into the workbench 100.

Further: the horizontal height distance between the driving shaft 320 and the brush 410 is equal to the distance between the driving shaft 320 and the polishing surface of the polishing disk 210.

In the using process of the processing device, firstly, the glass bottle 500 is placed into a grinding hole on the workbench 100 and placed on the grinding disc 210, and then the clamp 110 clamps the glass bottle 500 from two sides;

after the glass bottle 500 is fixed, the first driving shaft 220 drives the polishing disc 210 to rotate, and the bottom of the glass bottle 500 is polished through the rotation of the polishing disc 210;

after the glass bottle 500 is polished, the worker takes the glass bottle 500 off, when another glass bottle 500 is polished, the rotation of the second driving shaft 310 drives the transmission shaft 320 to rotate around the transmission shaft, because the transmission shaft 320 is provided with the bevel gear 331, the bevel gear 331 is engaged with the bevel gear 341, the transmission shaft 320 rotates around the second driving shaft 310, simultaneously, the bevel gear 331 makes a circular motion around the center of the bevel gear 341, and drives the transmission shaft 320 to rotate simultaneously with the motion, the rotation of the transmission shaft 320 drives the polishing assembly 200 fixed at one end to rotate, so that the polishing assembly 200 synchronizes the motion of the transmission shaft 320, when the second driving shaft 310 moves the polishing assembly 200 from the polishing position to the cleaning position through the transmission shaft 320, the polishing surface on the polishing disc 210 faces the bottom of the workbench 100, at the moment, the third driving shaft 420 drives the hairbrush 410 to horizontally reciprocate, the polishing surface of the polishing disc 210 is cleaned through the hairbrush 410, because the polishing surface is arranged downwards, the cleaned debris falls into the dust collection box 430, the debris is collected and processed by the dust collection box 430, and the dust collection box 430 is inserted into the workbench 100, so that when the dust collection box 430 is fully loaded, the dust collection box 430 can be drawn out of the workbench 100;

secondly, when a set of grinding assembly 200 moves from the grinding position to the cleaning position, another grinding assembly 200 after cleaning on the cleaning position can move to the grinding position, the waiting time of workers is reduced by utilizing a plurality of sets of grinding assemblies 200, and when the grinding assembly 200 moves to the grinding position, under the cooperation of the gear teeth on the helical gear 331 and the helical gear 341, the grinding surface of the grinding disc 210 can face the top of the workbench 100, at the moment, the glass bottle 500 can be ground at the bottom of the bottle after being continuously put in, and another set of grinding assembly 200 is cleaned while grinding.

The embodiments of the present invention have been described with reference to the drawings, but the present invention is not limited to the above-mentioned specific embodiments, which are only illustrative and not restrictive, and those skilled in the art can make many forms without departing from the spirit and scope of the present invention and the protection scope of the claims.

Claims (10)

1. The utility model provides a smart material spun gold glass bottle processingequipment, a serial communication port, workstation (100) and glass bottle (500) of arranging perpendicularly including the level are arranged, the hole of polishing has been seted up to workstation (100) upper table face, place in the hole inside of polishing bottom of glass bottle (500), anchor clamps (110) are installed to the both sides in hole of polishing, the inside of workstation (100) from left to right installs in proper order and polishes subassembly (200), transmission assembly (300), clearance subassembly (400), it is located the hole of polishing under to polish subassembly (200), it is used for polishing to glass bottle (500) bottle bottom to polish subassembly (200), transmission assembly (300) and polishing subassembly (200) cooperate, order about polishing subassembly (200) and rotate the polishing surface on it of in-process upset, clearance subassembly (400) are used for clearing up the adnexed piece on the polishing surface after the upset.

2. The fine-ground golden-wire glass bottle processing device as claimed in claim 1, wherein the grinding assembly (200) comprises a grinding disc (210) and a first driving shaft (220) which is vertically arranged, one end of the first driving shaft (220) is fixedly connected to the grinding disc (210), and the diameter of the grinding disc (210) is larger than the diameter of the bottom of the glass bottle (500).

3. The fine material golden silk glass bottle processing device according to claim 2, wherein the transmission assembly (300) comprises a second driving shaft (310), a driven part (340) and a driving part (330), the axial direction of the second driving shaft (310) is consistent with the axial direction of the first driving shaft (220), a transmission shaft (320) is installed at the upper end of the second driving shaft (310), the axis of the transmission shaft (320) is perpendicular to the axis of the second driving shaft (310), one end of the transmission shaft (320) is fixedly connected to the grinding assembly (200), the other end of the transmission shaft is rotatably connected to the second driving shaft (310), and the driven part (340) is matched with the driving part (330) and used for driving the transmission shaft (320) and the grinding assembly (200) to rotate around the second driving shaft (310) in the horizontal rotating process.

4. The fine material golden silk glass bottle processing device according to claim 3, wherein a driving part is installed at one end of the first driving shaft (220) far away from the polishing disc (210), and one end of the transmission shaft (320) far away from the second driving shaft (310) is fixedly connected with the driving part.

5. The apparatus as claimed in claim 3, wherein the connection between the drive shaft (320) and the drive member is at the center of gravity of the grinding assembly (200).

6. A refined spun-gold glass bottle processing apparatus as claimed in claim 3, wherein said grinding assemblies (200) are provided in a plurality of sets and are equally spaced around the circumference of said second drive shaft (310).

7. The fine material spun-gold glass bottle processing device according to claim 3, wherein the driving member (330) comprises a bevel gear (331), the bevel gear (331) is mounted on the transmission shaft (320), the axis of the transmission shaft (320) is collinear with the axis of the transmission shaft (320), the driven member (340) comprises a bevel gear (341), the bevel gear (341) is mounted on the inner wall of the workbench (100), the bevel gear (341) is meshed with the bevel gear (331), and the axis of the bevel gear (341) is collinear with the axis of the second driving shaft (310).

8. The apparatus as claimed in claim 3, wherein the cleaning assembly (400) comprises a third driving shaft (420) and a brush (410), the third driving shaft (420) is installed at one side of the second driving shaft (310), the axis of the third driving shaft (420) is perpendicular to the axis of the second driving shaft (310), the brush (410) is installed at one end of the third driving shaft (420), and the third driving shaft (420) drives the brush (410) to reciprocate and move horizontally.

9. The apparatus as claimed in claim 8, wherein the cleaning assembly (400) further comprises a dust collection box (430), the dust collection box (430) being inserted into the working table (100).

10. The apparatus as claimed in claim 8, wherein the horizontal distance between the driving shaft (320) and the brush (410) is equal to the distance between the driving shaft (320) and the polishing surface of the polishing plate (210).

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