CN107696455B

CN107696455B - Conveying mechanism of full-automatic double-material-channel bottle blowing machine

Info

Publication number: CN107696455B
Application number: CN201711135130.6A
Authority: CN
Inventors: 李伟
Original assignee: Jiangsu Xin Petroleum Machinery Co Ltd
Current assignee: Jiangsu Xin Petroleum Machinery Co., Ltd.
Priority date: 2017-11-16
Filing date: 2017-11-16
Publication date: 2019-12-27
Anticipated expiration: 2037-11-16
Also published as: CN107696455A

Abstract

The invention relates to the technical field of bottle blowing machines, in particular to a conveying mechanism of a full-automatic double-material-channel bottle blowing machine, which comprises a feeding device, a first blowing device and a second blowing device, wherein the feeding device comprises a material box, a first conveying belt, a slide way, a second conveying belt and a third conveying belt, the first blowing device and the second blowing device respectively comprise a conveying assembly, a blowing assembly, a cooling assembly, a blanking assembly and a reset assembly, the tail end of the third conveying belt is provided with a lifting plate, two sides of the lifting plate are respectively provided with a first lifting block and a second lifting block, and the tail end of the lifting plate is provided with a heating assembly. The special-shaped plate is adopted to replace an air clamp and an air cylinder, so that the demand on energy is reduced, and the cost of the bottle blowing machine is reduced.

Description

Conveying mechanism of full-automatic double-material-channel bottle blowing machine

Technical Field

The invention relates to the technical field of bottle blowing machines, in particular to a conveying mechanism of a full-automatic double-material-channel bottle blowing machine.

Background

The plastic is widely applied to various industries due to the advantages of lightness and larger toughness, and particularly, beverage packages in food are basically packaged by plastic bottles, the plastic bottles are produced by blow molding after bottle blanks are heated, automatic transportation of the bottle blanks in the blow molding process is basically realized, however, the existing bottle blanks need a large amount of air clamps and air cylinders to work in a matching way in the transportation process, the energy consumption of a bottle blowing machine is increased due to the use of the air clamps and the air cylinders, the cost of the bottle blowing machine is also increased, and aiming at the problems, the conveying mechanism of the full-automatic double-material-channel bottle blowing machine is provided.

Disclosure of Invention

The invention aims to provide a conveying mechanism of a full-automatic double-material-channel bottle blowing machine, aiming at the defects of the prior art.

In order to solve the above problems, the present invention provides the following technical solutions:

a conveying mechanism of a full-automatic double-material-channel bottle blowing machine comprises a feeding device, a first blow molding device and a second blow molding device which are symmetrically arranged on two sides of an output end of the feeding device, wherein the feeding device comprises a material box, a first conveying belt extending upwards from the bottom of the material box in an inclined mode, a slide way positioned at the tail end of the first conveying belt, a second conveying belt positioned above the slide way, and a third conveying belt positioned at the tail end of the slide way, the first blow molding device and the second blow molding device respectively comprise a conveying assembly, a blow molding assembly, a cooling assembly, a blanking assembly and a reset assembly, the blow molding assembly, the cooling assembly, the blanking assembly and the reset assembly are sequentially arranged on the conveying assembly along the conveying direction, a lifting plate used for lifting an embryo bottle is arranged at the tail end of the third conveying belt, and first lifting blocks and second lifting blocks are arranged on the lifting plate along two sides of the first blow molding device and the second blow molding device, the first lifting block and the second lifting block are arranged in parallel with the third conveyor belt, the vertical distance from one side, close to the first blowing device, of the first lifting block to the first blowing device is gradually reduced until the first lifting block is attached to the first blowing device, the vertical distance from one side, close to the second blowing device, of the second lifting block to the second blowing device is gradually reduced until the second lifting block is attached to the second blowing device, the heights of the first lifting block and the second lifting block are gradually increased along the direction, away from the third conveyor belt, of the first lifting block and the second lifting block respectively, and the tail end of the lifting plate is provided with a heating assembly for the conveying assembly to penetrate through.

Furthermore, be equipped with a plurality of baffle along first conveyer belt equidistant distribution on the first conveyer belt, every baffle is perpendicular with the length direction of conveyer belt and the length of every baffle all is the same with the width of conveyer belt, the both sides of first conveyer belt all are equipped with the baffle with the both ends laminating of baffle.

Furthermore, the inlet end of the slide way is lower than the tail end of the first conveying belt, the inlet end of the slide way is lower than the outlet end of the slide way, the width of the slide way is gradually reduced along the direction away from the first conveying belt until the width of the slide way is equal to the length of the bottle blanks, sliding grooves in sliding fit with the protruding portions of the bottle blanks are arranged on two sides of the tail end of the slide way, and limiting edges are arranged at the tail end of the slide way.

Furthermore, the second conveyer belt and the slide way are arranged in parallel, a plurality of limiting groups distributed at equal intervals are arranged on the second conveyer belt, each limiting group comprises four limiting columns distributed at equal intervals along the width direction of the second conveyer belt, and the length of each limiting column is smaller than or equal to the minimum distance from the second conveyer belt to the slide way.

Furthermore, be equipped with a plurality of equidistant distribution on the third conveyer belt with bottle embryo complex spacing groove, every spacing groove is circular-arc and the radius of its circular arc is the same with the radius of bottle embryo, the both sides of third conveyer belt all are equipped with the top board that is used for block bottle embryo.

Further, the conveying assembly comprises a conveying chain and a plurality of installation seats which are distributed at equal intervals along the conveying chain, clamping plates are arranged on two sides of the conveying chain, a hinging seat fixedly connected with the conveying chain is arranged on each installation seat, a station seat matched with bottle blanks in a splicing mode is hinged to each hinging seat, a groove is formed in the station seat, an insertion block matched with the groove in a splicing mode is arranged on each station seat, and a spring used for enabling the insertion block to reset is arranged in each groove.

Furthermore, the part of the hinged seat close to the inner side of the conveying chain is set to be a right angle for preventing the station seat from rotating towards the inner side of the conveying chain, and the part of the hinged seat close to the outer side of the conveying chain is set to be a round angle capable of enabling the station seat to rotate towards the outer side of the conveying chain.

Has the advantages that: according to the conveying mechanism of the full-automatic double-material-channel bottle blowing machine, disclosed by the invention, the bottle blanks are positioned at the tail end of the third conveying belt through the matching work of the first conveying belt, the slide way, the second conveying belt and the third conveying belt, the bottle blanks are positioned on the station seat through the matching work of the station seat and the compression plate, the bottle blanks are in a vertical state under the action of the lifting plate, the feeding process of the bottle blanks is completed, the bottle blanks move along with the conveying chain and sequentially pass through the working components arranged around the conveying chain, the automatic conveying of the bottle blanks in the blow molding process is completed, the manual workload is reduced, actions are realized by adopting a special-shaped plate structure, the use of air clamps and air cylinders in the production process is reduced, the energy demand is reduced, and the cost of the bottle blowing machine is reduced.

Drawings

FIG. 1 is a top view of a full-automatic double-material-channel bottle blowing machine;

FIG. 2 is a schematic view showing a partial three-dimensional structure of a conveying mechanism of a full-automatic double-material-channel bottle blowing machine;

FIG. 3 is a schematic view of a partial three-dimensional structure of a conveying mechanism of a full-automatic double-material-channel bottle blowing machine;

FIG. 4 is a schematic view showing a three-dimensional structure of a part of a conveying mechanism of a full-automatic double-material-channel bottle blowing machine;

FIG. 5 is a schematic view of a partially cut-away three-dimensional structure of a full-automatic double-material-channel bottle blowing machine;

FIG. 6 is a schematic diagram of a partially cut-away three-dimensional structure of a full-automatic double-material-channel bottle blowing machine;

FIG. 7 is a schematic perspective view of a full-automatic double-material-channel bottle blowing machine;

FIG. 8 is an enlarged view taken at A in FIG. 7;

FIG. 9 is a schematic perspective view of a full-automatic double-material-path bottle blowing machine;

FIG. 10 is an enlarged view at B of FIG. 9;

description of reference numerals: the device comprises a feeding device 1, a first blowing device 2, a second blowing device 3, a bin 4, a first conveyor belt 5, a partition plate 5a, a baffle plate 5b, a slide rail 6, a slide groove 5a, a limiting rib 5b, a second conveyor belt 7, a limiting column 7a, a third conveyor belt 8, a limiting groove 8a, an upper pressing plate 8b, a conveying assembly 9, a mounting seat 9a, a clamping plate 9b, a hinged seat 9c, a station seat 9d, an insertion block 9e, a blowing assembly 10, a first mold shell 10a, a second mold shell 10b, a first air cylinder 10c, a second air cylinder 10d, a cooling assembly 11, a cooling box 11a, a heat conduction layer 11b, a heat insulation layer 11c, an inlet pipe 11d, a water outlet pipe 11e, a blanking assembly 12, a first blanking plate 12a, a second blanking plate 12b, a resetting assembly 13, an upper pushing plate 13a, a compression plate 13b, a lifting plate 14, a first lifting block 14a and a second lifting block 14b, a heating assembly 15, a heating box 15a, a heating lamp 15b, and a convex mirror 15 c.

Detailed Description

The following detailed description of specific embodiments of the present invention is made with reference to the accompanying drawings and examples:

referring to fig. 1 to 10, the conveying mechanism of a full-automatic double-material-channel bottle blowing machine includes a feeding device 1, and a first blow molding device 2 and a second blow molding device 3 symmetrically disposed at two sides of an output end of the feeding device 1, where the feeding device 1 includes a material box 4, a first conveyor belt 5 extending obliquely upward from a bottom of the material box 4, a slide 6 located at a tail end of the first conveyor belt 5, a second conveyor belt 7 located above the slide 6, and a third conveyor belt 8 located at a tail end of the slide 6, the first blow molding device 2 and the second blow molding device 3 each include a conveying assembly 9, a blow molding assembly 10, a cooling assembly 11, a blanking assembly 12, and a reset assembly 13, the blow molding assembly 10, the cooling assembly 11, the blanking assembly 12, and the reset assembly 13 are sequentially disposed on the conveying assembly 9 along a conveying direction, a lifting plate 14 for lifting a bottle blank is disposed at a tail end of the third conveyor belt 8, the lifting plate 14 is provided with a first lifting block 14a and a second lifting block 14b along two sides of the first blowing device 2 and the second blowing device 3, the first lifting block 14a and the second lifting block 14b are arranged in parallel with the third conveyor belt 8, the vertical distance from one side of the first lifting block 14a close to the first blowing device 2 is gradually reduced until the first lifting block is attached to the first blowing device 2, the vertical distance from one side of the second lifting block 14b close to the second blowing device 3 is gradually reduced until the second lifting block is attached to the second blowing device 3, the heights of the first lifting block 14a and the second lifting block 14b are gradually increased along the direction of the first lifting block and the second lifting block away from the third conveyor belt 8, and the tail end of the lifting plate 14 is provided with a heating assembly 15 for the conveying assembly 9 to pass through.

Referring to fig. 2 to 4, an inlet end of the slide 6 is lower than a tail end of the first conveyor belt 5, an inlet end of the slide 6 is lower than an outlet end thereof, a width of the slide 6 is gradually reduced along a direction away from the first conveyor belt 5 until the width is equal to a length of the bottle preform, both sides of the tail end of the slide 6 are provided with slide grooves 6a in sliding fit with the bottle preform protruding portions, and the tail end of the slide 6 is provided with a limiting rib 6 b; the baffle 5a can drive the bottle embryo in the workbin 4 and upwards transport to the slide 6 along with first conveyer belt 5 on, the baffle 5b of 5 both sides of first conveyer belt can prevent that the bottle embryo on the first conveyer belt 5 from the side landing.

The inlet end of the slide way 6 is lower than the tail end of the first conveyor belt 5, the inlet end of the slide way 6 is lower than the outlet end of the slide way 6, the width of the slide way 6 is gradually reduced along the direction away from the first conveyor belt 5 until the width of the slide way is equal to the length of the bottle embryo, sliding grooves 6a which are in sliding fit with protruding parts of the bottle embryo are arranged on two sides of the tail end of the slide way 6, and a limiting edge 6b is arranged at the tail end of; the bottle embryo that slide 6 slope setting made first conveyer belt 5 transport can follow slide 6 landing to third conveyer belt 8 on, and the bottle embryo that rolls down on the convenient first conveyer belt 5 of the entry width broad of slide 6 is the skew state gets into, and spacing arris 6b can avoid bottle embryo landing speed too fast, does not reach the assigned position when making it get into third conveyer belt 8.

The second conveyor belt 7 is arranged in parallel with the slide way 6, a plurality of limit groups distributed at equal intervals are arranged on the second conveyor belt 7, each limit group comprises four limit columns 7a distributed at equal intervals along the width direction of the second conveyor belt 7, and the length of each limit column 7a is smaller than or equal to the minimum distance from the second conveyor belt 7 to the slide way 6; the second conveyor belt 7 runs to drive the limiting columns 7a to move, the limiting columns 7a at the lower portions of the second conveyor belt 7 move from the inlet of the slide 6 to the outlet of the slide 6 and drive bottle blanks in the slide 6 to slide along the slide 6, and the four limiting columns 7a arranged side by side can enable the length direction of each bottle blank to be perpendicular to the length direction of the slide 6, so that the bottle blanks are prevented from being inclined in the slide 6 and being clamped by the slide 6.

The third conveyor belt 8 is provided with a plurality of limit grooves 8a which are distributed at equal intervals and matched with the bottle blanks, each limit groove 8a is arc-shaped, the radius of the arc is the same as that of the bottle blank, and two sides of the third conveyor belt 8 are provided with upper pressing plates 8b for clamping the bottle blanks; each limiting groove 8a corresponds to one bottle blank for transportation, and the radius of each limiting groove 8a is the same as that of the bottle blank, so that the bottle blanks are prevented from moving back and forth in the conveying process.

Referring to fig. 9 and 10, each conveying assembly 9 comprises a conveying chain and a plurality of mounting seats 9a which are distributed at equal intervals along the conveying chain, clamping plates 9b are arranged on two sides of the conveying chain, a hinge seat 9c fixedly connected with the conveying chain is arranged on each mounting seat 9a, a station seat 9d in inserting fit with a bottle blank is hinged on each hinge seat 9c, a groove is arranged in each station seat 9d, an inserting block 9e in inserting fit with the groove is arranged on each station seat, and a spring for resetting the inserting block 9e is arranged in each groove; mount pad 9a and articulated seat 9c fixed connection, make articulated seat 9c dismantle from mount pad 9a fast, because the distance between per two mount pads 9a is fixed, consequently, when the plastic bottle of equidimension not to blow molding to different bottle embryo, can install articulated seat 9c on two mount pads 9a of a plurality of mount pads 9a apart from, thereby make the distance between two adjacent station seats 9d can change, the splint 9b of transfer chain both sides can block station seat 9d, avoid it to rotate in data send process.

The part of the hinged seat 9c close to the inner side of the conveying chain is set to be a right angle for preventing the station seat 9d from rotating towards the inner side of the conveying chain, and the part of the hinged seat 9c close to the outer side of the conveying chain is set to be a round angle capable of enabling the station seat 9d to rotate towards the outer side of the conveying chain; the right angle and the rounded angle on the hinge seat 9c enable the station seat 9d to rotate at an angle of 90 degrees only in one direction.

Referring to fig. 5, the heating assembly 15 is located in a straight line section of the conveying assembly 9, the heating assembly 15 includes a heating box 15a and a heating lamp 15b arranged in the heating box 15a, a containing cavity is arranged in the heating box 15a, the heating lamp 15b is located in the middle of the containing cavity, two ends of the heating lamp 15b are respectively fixedly connected with a front wall and a rear wall of the containing cavity, an inner wall of the containing cavity is made of a reflective material, convex mirrors 15c are arranged at upper and lower ends of the containing cavity, a box body of the heating box 15a is of a double-layer structure, and an outer layer of the heating box is made of a heat insulation; the inner wall of the light-reflecting accommodating cavity can prevent the temperature in the heating box 15a from radiating through heat radiation, the outer heat-insulating layer 11c of the heating box 15a can reduce heat conduction and radiation, the loss of the temperature in the heating box 15a is greatly reduced, and the convex mirror 15c can reflect upward and downward emitted light to bottle blanks on the first conveying assembly 9 and the second conveying assembly 9 to enhance the heating effect of the bottle blanks.

Referring to fig. 6, each of the blow molding assemblies 10 includes a first mold housing 10a and a second mold housing 10b which cooperate with each other to form a mold, the first mold housing 10a and the second mold housing 10b are symmetrically disposed about the conveyor chain, and the rear ends of the first mold housing 10a and the second mold housing 10b are respectively provided with a first cylinder 10c and a second cylinder 10d for driving the same; the first blow-molding assembly 10 and the second blow-molding assembly 10 are all of the prior art and will not be described in detail herein.

The cooling assemblies 11 respectively comprise a cooling box 11a and a pipeline arranged in the box body of the cooling box 11a, the cooling box 11a is of a bilateral structure, the inner layer and the outer layer of the cooling box are respectively a heat conduction layer 11b and a heat insulation layer 11c, and the outer wall of the cooling box is provided with a water inlet pipe 11d and a water outlet pipe 11 e; the cooling liquid is conveyed into the cooling box 11a through the pipeline and reduces the temperature in the cooling box 11a, so that the temperature of the plastic bottles which are just blown through the cooling box 11a is reduced, the plastic bottles are rapidly cooled and shaped, and the plastic bottles are prevented from being naturally cooled on the rail, so that the transportation rail is overlong.

Referring to fig. 7 and 8, the blanking assemblies 12 are located in a straight line section of the conveying assembly 9, each blanking assembly 12 includes a first blanking plate 12a and a second blanking plate 12b respectively disposed inside and outside the conveying chain, the first blanking plate 12a and the second blanking plate 12b are parallel to each other, a distance between the first blanking plate 12a and the second blanking plate 12b is greater than a minimum diameter of the bottle embryo and smaller than a maximum diameter of the bottle embryo, heights of the first blanking plate 12a and the second blanking plate 12b are gradually increased along a conveying direction of the conveying chain, and a growth speed of the height of the first blanking plate 12a is greater than a growth speed of the height of the second blanking plate 12 b; the plastic bottle that the blowing was accomplished moves along with station seat 9d, when reacing first flitch 12a and second flitch 12b down, because the height of first flitch 12a and second flitch 12b is gone up gradually down for the plastic bottle is gradually lifted up from station seat 9d, because the height increase rate of inboard first flitch 12a is greater than the second plastic slab, makes the plastic bottle that is lifted up to incline to the outside, is separated from station seat 9d when the plastic bottle, just can drop to the conveying chain outside by priority.

Referring to fig. 9, the reset assemblies 13 each include a push-up plate 13a and a compression plate 13b, the push-up plate 13a is located above the conveyor chain, the horizontal height of the lower end surface of the push-up plate 13a is equal to or higher than the upper end surface of the hinge seat 9c, the width of the push-up plate 13a gradually increases along the conveying direction of the conveyor chain until the width is greater than or equal to the width of the mounting seat 9a, the compression plate 13b is located beside the conveyor chain, and the distance from the compression plate 13b to the conveyor chain gradually decreases along the moving direction of the conveyor chain until the compression plate 13b can completely retract the insert block 9e into the station seat 9 d; when the station seat 9d which finishes blanking passes through the upper pushing plate 13a, the width of the upper pushing plate 13a is gradually increased, so that the station seat 9d gradually rotates to the outer side of the conveying chain and finally rotates by 90 degrees, and when the station seat 9d after rotation passes through the compression plate 13b, the compression plate 13b is closer to the conveying chain, so that the insertion block 9e gradually contracts into the station seat 9 d.

The working principle is as follows: according to the invention, bottle blanks are put into a material box 4, a partition plate 5a on a first conveyor belt 5 can drive the bottle blanks to move upwards until the bottle blanks fall into a slide way 6, the bottle blanks slide on the slide way 6 to the outlet end of the slide way 6, a second conveyor belt 7 above the slide way 6 rotates and drives a limiting column 7a on the second conveyor belt 7 to push the bottle blanks to move, the length direction of the bottle blanks is perpendicular to the length direction of the slide way 6, the bottle blanks falling into a groove on a third conveyor belt 8 matched with the slide way 6 through the slide way 6 are conveyed to the tail end by the third conveyor belt 8, at the moment, station seats 9d on two sides of the third conveyor belt 8 just passing through a compression plate 13b respectively move to two ends of the bottle blanks, insertion blocks 9e in the station seats 9d at the openings of the bottle blanks pop out and insert the bottle blanks under the action of springs, the station seats 9d drive the bottle blanks to continue to move, under the effect of the lifting block which is gradually widened and heightened, the horizontal state is changed into the vertical state, the vertical bottle blanks are driven by the conveying chain to complete blow molding through the heating assembly 15, the blow molding assembly 10, the cooling assembly 11 and the blanking assembly 12, and the bottle blanks of the bottle blowing device are automatically conveyed.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any minor modifications, equivalent changes and modifications made to the above embodiment according to the technical spirit of the present invention are within the technical scope of the present invention.

Claims

1. The utility model provides a full-automatic double-material-channel bottle blowing machine's conveying mechanism which characterized in that: the automatic feeding device comprises a feeding device (1), a first blow molding device (2) and a second blow molding device (3) which are symmetrically arranged on two sides of an output end of the feeding device (1), wherein the feeding device (1) comprises a material box (4), a first conveying belt (5) which extends upwards from the bottom of the material box (4) in an inclined mode, a slide way (6) which is positioned at the tail end of the first conveying belt (5), a second conveying belt (7) which is positioned above the slide way (6) and a third conveying belt (8) which is positioned at the tail end of the slide way (6), the first blow molding device (2) and the second blow molding device (3) respectively comprise a conveying assembly (9), a blow molding assembly (10), a cooling assembly (11), a blanking assembly (12) and a reset assembly (13), and the blow molding assembly (10), the cooling assembly (11), the blanking assembly (12) and the reset assembly (13) are sequentially arranged on the conveying assembly (9) along, the tail end of the third conveyor belt (8) is provided with a lifting plate (14) for lifting bottle blanks, the lifting plate (14) is provided with a first lifting block (14 a) and a second lifting block (14 b) along two sides of the first blow molding device (2) and the second blow molding device (3), the first lifting block (14 a) and the second lifting block (14 b) are arranged in parallel with the third conveyor belt (8), the vertical distance from one side of the first lifting block (14 a) close to the first blow molding device (2) is gradually reduced until the first lifting block is attached to the first blow molding device (2), the vertical distance from one side of the second lifting block (14 b) close to the second blow molding device (3) is gradually reduced until the second blow molding device (3) is attached, the heights of the first lifting block (14 a) and the second lifting block (14 b) are respectively gradually increased along the direction of the lifting block away from the third conveyor belt (8), the tail end of the lifting plate (14) is provided with a heating assembly (15) for the conveying assembly (9) to pass through.

2. The conveying mechanism of the full-automatic double-material-channel bottle blowing machine according to claim 1 is characterized in that: be equipped with on first conveyer belt (5) along a plurality of baffle (5 a) of first conveyer belt (5) equidistant distribution, every baffle (5 a) is perpendicular with the length direction of conveyer belt and the length of every baffle (5 a) all is the same with the width of conveyer belt, the both sides of first conveyer belt (5) all are equipped with baffle (5 b) with the both ends laminating of baffle (5 a).

3. The conveying mechanism of the full-automatic double-material-channel bottle blowing machine according to claim 2 is characterized in that: the inlet end of the slide way (6) is lower than the tail end of the first conveying belt (5), the inlet end of the slide way (6) is lower than the outlet end of the slide way, the width of the slide way (6) is gradually reduced along the direction of the slide way far away from the first conveying belt (5) until the width of the slide way is equal to the length of the bottle embryo, sliding grooves (6 a) which are in sliding fit with the protruding parts of the bottle embryo are formed in the two sides of the tail end of the slide way (6), and limiting ribs (6 b) are arranged at the.

4. The conveying mechanism of the full-automatic double-material-channel bottle blowing machine according to claim 3 is characterized in that: second conveyer belt (7) and slide (6) parallel arrangement are equipped with a plurality of spacing group of equidistant distribution on second conveyer belt (7), and every spacing group includes four spacing post (7 a) of equidistant distribution along second conveyer belt (7) width direction, and the length of spacing post (7 a) is less than or equal to the minimum distance of second conveyer belt (7) to slide (6).

5. The conveying mechanism of the full-automatic double-material-channel bottle blowing machine according to claim 1 is characterized in that: the third conveyor belt (8) is provided with a plurality of limit grooves (8 a) which are distributed at equal intervals and matched with the bottle blanks, each limit groove (8 a) is arc-shaped, the radius of the arc of each limit groove is the same as that of each bottle blank, and the two sides of the third conveyor belt (8) are provided with upper press plates (8 b) used for clamping the bottle blanks.

6. The conveying mechanism of the full-automatic double-material-channel bottle blowing machine according to claim 1 is characterized in that: conveying component (9) all include the transfer chain and along a plurality of mount pad (9 a) of transfer chain equidistant distribution, the both sides of transfer chain all are equipped with splint (9 b), are equipped with rather than fixed connection's articulated seat (9 c) on mount pad (9 a), and it has station seat (9 d) of pegging graft complex with the bottle embryo to articulate on every articulated seat (9 c), the inside of station seat (9 d) is equipped with the recess, is equipped with on station seat (9 d) and pegs graft complex inserted block (9 e) with the recess, is equipped with the spring that is used for making inserted block (9 e) reset in the recess.

7. The conveying mechanism of the full-automatic double-material-channel bottle blowing machine according to claim 6, characterized in that: articulated seat (9 c) are close to the inboard part of transfer chain and set up to prevent that station seat (9 d) are to the inboard pivoted right angle of transfer chain, and articulated seat (9 c) are close to the outside part of transfer chain and set up to letting station seat (9 d) to the outside pivoted fillet of transfer chain.