CN214571521U

CN214571521U - Glass annealing device is used in glass bottle production

Info

Publication number: CN214571521U
Application number: CN202120338342.XU
Authority: CN
Inventors: 黄辉
Original assignee: Jiangxi Lantian Glass Products Co ltd
Current assignee: Jiangxi Lantian Glass Products Co ltd
Priority date: 2021-02-06
Filing date: 2021-02-06
Publication date: 2021-11-02
Anticipated expiration: 2031-02-06

Abstract

The utility model discloses a glass annealing device is used in glass bottle production, including the base, still including the block structure of the even refrigerated rotating-structure of being convenient for, the quick assembly disassembly collection box of being convenient for and the clamping structure that can centre gripping glass bottle fast, the landing leg is all installed to four corners on base top, and the top welding of landing leg one side has the shell, the deflector is all installed to the both sides of shell bottom, the block structure sets up in the inside bottom of deflector. The utility model discloses an on inserting the bull stick with the bottleneck of glass bottle, promote simultaneously and make its extrusion movable block, and then make the movable block remove along the bull stick, open through driving installation cover control limiting rod, utilize the direction rotation movable block of slide in the sliding block afterwards for promote the spring and push back more distances with the movable block, and then make the gag lever post shrink with the body centre gripping, it is very convenient, realized the quick clamping function of device.

Description

Glass annealing device is used in glass bottle production

Technical Field

The utility model relates to a glass production technical field specifically is a glass annealing device is used in glass bottle production.

Background

Glass bottles are common containers in our lives, whether beverages, foods or condiments, and are mostly contained in glass bottles, which undergo a multi-step process during the manufacturing process, wherein the glass bottles are annealed in order to reduce residual stress, stabilize dimensions, reduce deformation and crack tendency, which is usually performed in an annealing furnace.

The conventional glass annealing apparatus has the following disadvantages:

(1) the glass bottle is not clamped quickly and stably, and the glass is easy to damage due to shaking;

(2) the cooling effect of each position of the glass bottle is different, so that the annealing effect of the glass bottle is not good enough;

(3) the glass bottles during annealing may precipitate impurities which accumulate in the furnace and are not easily cleaned.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a glass annealing device is used in glass bottle production to when solving the water conservancy diversion to the patient that proposes in the above-mentioned background art, the honeycomb duct is not stable enough, may destroy the problem of wound.

In order to achieve the above object, the utility model provides a following technical scheme: a glass annealing device for glass bottle production comprises a base, a rotating structure convenient for uniform cooling, a clamping structure convenient for rapid disassembly and assembly of a collecting box and a clamping structure capable of rapidly clamping a glass bottle;

the four corners of the top end of the base are provided with supporting legs, the top end of one side of each supporting leg is welded with a shell, two sides of the bottom end of each shell are provided with guide plates, and the clamping structures are arranged at the bottom ends inside the guide plates;

a collecting box is arranged below the shell, guide blocks are arranged on two sides of the collecting box, one side of each guide block extends into the guide plate, a protective door is arranged at one end of the shell, an air pump is arranged on one side of the top end of the shell, an air exhaust pipe is arranged at the input end of the air pump, an air supply pipe is arranged at the output end of the air pump, the bottom end of the air supply pipe penetrates into the shell, a driving motor is arranged in the middle position of the top end of the shell, a main rod is arranged at the output end of the driving motor through a rotating shaft, the bottom end of the main rod is connected with the bottom end of the interior of the shell through a bearing, and the rotating structure is arranged on the inner wall of the shell;

the rotating rod is evenly installed on the outer wall of the main rod inside the shell through the rotating shaft, and the clamping structure is arranged on the outer wall of the rotating rod.

Preferably, the clamping structure include the slide all evenly sets up the outer wall in the bull stick, the outer wall of bull stick all overlaps and is equipped with the movable block, and the inner wall of movable block all installs three sliding block, the bottom of sliding block all extends to the inside of slide, four installation covers are all installed through the articulated elements to the outer wall of movable block, one side of bull stick outer wall all overlaps and is equipped with rotatory piece, and just the outer wall of rotatory piece all installs four gag levers through the articulated elements, one end of gag lever post all runs through to one side of installation cover, all install the promotion spring between one side of rotatory piece and movable block.

Preferably, each group of the slide ways is provided with three slide ways, and the slide ways are U-shaped like.

Preferably, revolution mechanic includes fixed plate, ash leakage hole, ring gear and gear, the fixed plate is all installed in the inner wall of shell, and the top of fixed plate all runs through and has a plurality of ash leakage holes, the ring gear is all installed to the intermediate position department on fixed plate top, the outer wall of bull stick is all located to the gear cover.

Preferably, nine gears are arranged, and the gears are meshed with the gear ring.

Preferably, the block structure includes reset spring, pull rod, spout, slider, fixture block and draw-in groove, the bottom of guide block is all seted up to the draw-in groove, the inside of deflector bottom is all seted up to the spout, two reset spring are all installed to the inside bottom of spout, and reset spring's top installs the slider, the fixture block has all been welded on the top of slider, and the top of fixture block all extends to the inside of draw-in groove, the bottom of slider has all been welded the pull rod, and the bottom of pull rod all extends to the below of deflector.

Preferably, the moving distance of the sliding block is less than or equal to the depth of the sliding groove, and the maximum moving distance of the sliding block is greater than the length of the clamping block.

Compared with the prior art, the beneficial effects of the utility model are that:

(1) the bottle mouth of the glass bottle is inserted into the rotating rod through the rotating rod, the movable block, the limiting rod, the mounting sleeve, the slide way, the sliding block and the pushing spring, the movable block is extruded by pushing the rotating rod, the movable block moves along the rotating rod, the limiting rod is controlled to be opened by driving the mounting sleeve, and then the movable block is rotated by utilizing the guide of the slide way in the sliding block, so that the pushing spring pushes the movable block back for more distances, the limiting rod is contracted to clamp the bottle body, the bottle body clamping device is very convenient, and the quick clamping function of the device is realized;

(2) by arranging the rotating rod, the gear, the toothed ring and the main rod, the rotation of the rotating rod can drive the gear to roll on the toothed ring, so that the rotating rod rotates around the main rod and simultaneously rotates around the rotating rod, all positions of glass bottles on the rotating rod can be uniformly cooled, and the uniform cooling function of the device is realized;

(3) the device is provided with a pull rod, a slide block, a return spring and a clamping block. Draw-in groove, deflector, collection box and guide block stimulate the pull rod for the pull rod drives the slider and overcomes reset spring and removes, and then makes the fixture block withdraw from the draw-in groove, makes the guide block no longer receive the restriction at the inside removal of deflector, can will collect the box fast and take off, carries out centralized processing to its inside impurity, has realized the concentrated clearance function of device.

Drawings

Fig. 1 is a schematic front view of a cross-sectional structure of the present invention;

fig. 2 is a schematic top view of the cross-sectional structure of the housing of the present invention;

FIG. 3 is a schematic top view of the slide and slide assembly of the present invention;

fig. 4 is an enlarged schematic structural view of a point a in fig. 1 according to the present invention;

fig. 5 is an enlarged schematic structural diagram of the position B in fig. 1 according to the present invention.

In the figure: 1. a rotating structure; 101. a fixing plate; 102. ash leakage holes; 103. a toothed ring; 104. a gear; 2. a snap-fit structure; 201. a return spring; 202. a pull rod; 203. a chute; 204. a slider; 205. a clamping block; 206. a card slot; 3. a support leg; 4. a base; 5. a housing; 6. a main rod; 7. a collection box; 8. a rotating rod; 9. a drive motor; 10. an air supply pipe; 11. an air pump; 12. an air exhaust pipe; 13. a protective door; 14. a slideway; 15. a slider; 16. a guide plate; 17. a guide block; 18. a limiting rod; 19. a push spring; 20. Rotating the block; 21. a movable block; 22. and (7) installing a sleeve.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Example 1: referring to fig. 1-5, a glass annealing device for glass bottle production comprises a base 4, a rotating structure 1 convenient for uniform cooling, a clamping structure 2 convenient for rapid disassembly and assembly of a collecting box, and a clamping structure capable of rapidly clamping a glass bottle;

the four corners of the top end of the base 4 are respectively provided with a supporting leg 3, the top end of one side of each supporting leg 3 is welded with a shell 5, two sides of the bottom end of each shell 5 are respectively provided with a guide plate 16, and the clamping structure 2 is arranged at the bottom end inside each guide plate 16;

a collecting box 7 is arranged below the shell 5, guide blocks 17 are mounted on two sides of the collecting box 7, one side of each guide block 17 extends into a guide plate 16, a protective door 13 is mounted at one end of the shell 5, an air pump 11 is mounted on one side of the top end of the shell 5, the type of the air pump 11 can be AS26, an air exhaust pipe 12 is mounted at the input end of the air pump 11, an air supply pipe 10 is mounted at the output end of the air pump 11, the bottom end of the air supply pipe 10 penetrates into the shell 5, a driving motor 9 is mounted in the middle position of the top end of the shell 5, the type of the driving motor 9 can be 86BL, a main rod 6 is mounted at the output end of the driving motor 9 through a rotating shaft, the bottom end of the main rod 6 is connected with the bottom end inside the shell 5 through a bearing, and the rotating structure 1 is arranged on the inner wall of the shell 5;

the outer walls of the main rods 6 in the shell 5 are uniformly provided with rotating rods 8 through rotating shafts, and the clamping structures are arranged on the outer walls of the rotating rods 8;

referring to fig. 1-5, a glass annealing device for glass bottle production further comprises a clamping structure, the clamping structure comprises a slide way 14, the slide way 14 is uniformly arranged on the outer wall of a rotating rod 8, the outer wall of the rotating rod 8 is sleeved with a movable block 21, the inner wall of the movable block 21 is provided with three sliding blocks 15, the bottom ends of the sliding blocks 15 extend into the slide way 14, the outer wall of the movable block 21 is provided with four mounting sleeves 22 through hinges, one side of the outer wall of the rotating rod 8 is sleeved with a rotating block 20, the outer wall of the rotating block 20 is provided with four limiting rods 18 through hinges, one ends of the limiting rods 18 penetrate through one sides of the mounting sleeves 22, and a pushing spring 19 is arranged between the rotating block 20 and one side of the movable block 21;

three slideways 14 are arranged in each group, and the shape of each slideway 14 is similar to a U shape;

specifically, as shown in fig. 1, fig. 3 and fig. 5, the bottle mouth of the glass bottle is inserted into the rotating rod 8, and the glass bottle is pushed to extrude the movable block 21, so that the movable block 21 moves along the rotating rod 8, the limiting rod 18 is controlled to be opened by driving the mounting sleeve 22, and then the movable block 21 is rotated by the guide of the slide way 14 in the sliding block 15, so that the pushing spring 19 pushes the movable block 21 back for more distances, and the limiting rod 18 is contracted to clamp the bottle body, which is very convenient.

Example 2: the rotating structure 1 comprises a fixed plate 101, a plurality of ash leakage holes 102, a toothed ring 103 and gears 104, wherein the fixed plate 101 is arranged on the inner wall of the shell 5, the top ends of the fixed plate 101 are provided with the ash leakage holes 102 in a penetrating manner, the toothed ring 103 is arranged in the middle of the top end of the fixed plate 101, and the gears 104 are sleeved on the outer wall of the rotating rod 8;

nine gears 104 are arranged, and the gears 104 are meshed with the gear ring 103;

specifically, as shown in fig. 1 and 2, the rotation of the rotating rod 8 drives the gear 104 to roll on the toothed ring 103, so that the rotating rod 8 rotates around itself while rotating around the main rod 6, and thus, each position of the glass bottle on the rotating rod 8 can be uniformly cooled.

Example 3: the clamping structure 2 comprises return springs 201, pull rods 202, sliding grooves 203, sliding blocks 204, clamping blocks 205 and clamping grooves 206, the clamping grooves 206 are formed in the bottom ends of the guide blocks 17, the sliding grooves 203 are formed in the bottom ends of the guide plates 16, the two return springs 201 are mounted at the bottom ends of the sliding grooves 203, the sliding blocks 204 are mounted at the top ends of the return springs 201, the clamping blocks 205 are welded at the top ends of the sliding blocks 204, the top ends of the clamping blocks 205 extend into the clamping grooves 206, the pull rods 202 are welded at the bottom ends of the sliding blocks 204, and the bottom ends of the pull rods 202 extend below the guide plates 16;

the moving distance of the sliding block 204 is less than or equal to the depth of the sliding groove 203, and the maximum moving distance of the sliding block 204 is greater than the length of the fixture block 205;

specifically, as shown in fig. 1 and 4, the pull rod 202 is pulled, so that the pull rod 202 drives the slider 204 to move against the return spring 201, and further the fixture block 205 exits from the fixture groove 206, so that the movement of the guide block 17 inside the guide plate 16 is not limited, and the collection box 7 can be quickly taken down to perform centralized processing on the impurities inside the collection box.

The working principle is as follows: when using this device, at first, open guard gate 13, insert the bottleneck of glass bottle on the bull stick 8, promote simultaneously and make its extrusion movable block 21, and then make movable block 21 remove along the bull stick 8, open through driving installation cover 22 control gag lever post 18, utilize the direction rotation movable block 21 of slide 14 in sliding block 15 afterwards, make and promote spring 19 and push back more distances with movable block 21, and then make gag lever post 18 shrink with the body centre gripping, it is very convenient.

Then, after the glass bottle is placed, the sliding block 15 is closed, the air pump 11 is started at the same time, cold air is fed in through the air exhaust pipe 12 and the air supply pipe 10, the driving motor 9 is started, the driving motor 9 drives the main rod 6 to rotate, so that the rotating rod 8 rotates around the driving motor 9, and meanwhile, the gear 104 is driven to roll on the toothed ring 103 due to the rotation of the rotating rod 8, so that the rotating rod 8 rotates around itself, and therefore all positions of the glass bottle on the rotating rod 8 can be uniformly cooled.

Finally, the glass bottle can separate out impurities in the tempering process, the impurities finally fall into the collection box 7 through the ash leakage holes 102, and when sufficient impurities are collected in the collection box 7, the pull rod 202 can be pulled, so that the pull rod 202 drives the sliding block 204 to overcome the movement of the return spring 201, the clamping block 205 is further made to exit from the clamping groove 206, the movement of the guide block 17 in the guide plate 16 is not limited any more, the collection box 7 can be taken down quickly, and the impurities in the collection box are subjected to centralized processing.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. The utility model provides a glass annealing device is used in glass bottle production, includes base (4), its characterized in that: the glass bottle fast-cooling device also comprises a rotating structure (1) convenient for uniform cooling, a clamping structure (2) convenient for fast dismounting and mounting the collecting box and a clamping structure capable of fast clamping the glass bottle;

the four corners of the top end of the base (4) are respectively provided with a supporting leg (3), the top end of one side of each supporting leg (3) is welded with a shell (5), two sides of the bottom end of each shell (5) are respectively provided with a guide plate (16), and the clamping structure (2) is arranged at the bottom end inside each guide plate (16);

a collecting box (7) is arranged below the shell (5), guide blocks (17) are arranged on two sides of the collecting box (7), one side of the guide block (17) extends into the guide plate (16), one end of the shell (5) is provided with a protective door (13), an air pump (11) is arranged on one side of the top end of the shell (5), an air suction pipe (12) is arranged at the input end of the air pump (11), an air feeding pipe (10) is arranged at the output end of the air pump (11), the bottom end of the air supply pipe (10) penetrates into the shell (5), a driving motor (9) is arranged in the middle position of the top end of the shell (5), and the output end of the driving motor (9) is provided with a main rod (6) through a rotating shaft, the bottom end of the main rod (6) is connected with the bottom end inside the shell (5) through a bearing, and the rotating structure (1) is arranged on the inner wall of the shell (5);

rotating rods (8) are evenly arranged on the outer wall of the main rod (6) inside the shell (5) through rotating shafts, and the clamping structure is arranged on the outer wall of each rotating rod (8).

2. The glass annealing device for producing glass bottles of claim 1, wherein: clamping structure includes slide (14) all evenly set up the outer wall in bull stick (8), the outer wall of bull stick (8) all overlaps and is equipped with movable block (21), and the inner wall of movable block (21) all installs three sliding block (15), the bottom of sliding block (15) all extends to the inside of slide (14), four installation covers (22) are all installed through the articulated elements to the outer wall of movable block (21), one side of bull stick (8) outer wall all overlaps and is equipped with rotatory piece (20), and the outer wall of rotatory piece (20) all installs four gag lever posts (18) through the articulated elements, the one end of gag lever post (18) all runs through to one side of installation cover (22), all install between one side of rotatory piece (20) and movable block (21) and promote spring (19).

3. The glass annealing device for producing glass bottles of claim 2, wherein: each group of the slide ways (14) is provided with three slide ways, and the slide ways (14) are U-shaped.

4. The glass annealing device for producing glass bottles of claim 1, wherein: rotating-structure (1) is including fixed plate (101), ash leakage hole (102), ring gear (103) and gear (104), fixed plate (101) are all installed in the inner wall of shell (5), and the top of fixed plate (101) all runs through and have a plurality of ash leakage holes (102), ring gear (103) are all installed to the intermediate position department on fixed plate (101) top, the outer wall of bull stick (8) is all located in gear (104) cover.

5. The glass annealing device for producing glass bottles of claim 4, wherein: nine gears (104) are arranged, and the gears (104) are meshed with the gear ring (103).

6. The glass annealing device for producing glass bottles of claim 1, wherein: block structure (2) include reset spring (201), pull rod (202), spout (203), slider (204), fixture block (205) and draw-in groove (206), the bottom of guide block (17) is all seted up in draw-in groove (206), the inside in deflector (16) bottom is all seted up in spout (203), two reset spring (201) are all installed to the inside bottom of spout (203), and install slider (204) on the top of reset spring (201), fixture block (205) have all been welded on the top of slider (204), and the top of fixture block (205) all extends to the inside of draw-in groove (206), pull rod (202) have all been welded to the bottom of slider (204), and the bottom of pull rod (202) all extends to the below of deflector (16).

7. The glass annealing device for producing glass bottles of claim 6, wherein: the moving distance of the sliding block (204) is less than or equal to the depth of the sliding groove (203), and the maximum moving distance of the sliding block (204) is greater than the length of the clamping block (205).