CN216360228U

CN216360228U - Conveying mechanism for plastic ampoule bottles

Info

Publication number: CN216360228U
Application number: CN202122973244.6U
Authority: CN
Inventors: 颜钊强; 陈天生; 谢振华; 王维民; 邓晓; 陈思
Original assignee: Foshan Map Reading Technology Co ltd
Current assignee: Foshan Map Reading Technology Co ltd
Priority date: 2021-11-30
Filing date: 2021-11-30
Publication date: 2022-04-22
Anticipated expiration: 2031-11-30

Abstract

The utility model discloses a conveying mechanism of a plastic ampoule bottle, which comprises a first conveying section, a second conveying section, a slide way, an intercepting cylinder, a pushing assembly and a stopping assembly, wherein the first conveying section is arranged on the first conveying section; the terminal end of the first transportation section is connected with the starting end of the second transportation section; the terminal end of the second transportation section is connected with the initial end of the slide way, and the transportation speed of the second transportation section is greater than that of the first transportation section; the terminal end of the second transport section is contiguous with the beginning of the chute. By designing the transport speed of the second transport section to be greater than the transport speed of the first transport section, differential transport is achieved. In this way, when the row of plastic ampoules at the end of the first transportation section contacts the second transportation section, the row of plastic ampoules is transported forward at a speed higher than the other rows of plastic ampoules in the first transportation section, the distance between the row of plastic ampoules and the next row of plastic ampoules is increased, and the continuous row of plastic ampoules is converted into interval transportation.

Description

Conveying mechanism for plastic ampoule bottles

Technical Field

The utility model relates to the technical field of transportation of medical packaging containers, in particular to a transportation mechanism of a plastic ampoule bottle.

Background

The traditional ampoule bottle is a small glass container for containing liquid medicine, the capacity is generally 1-25 ml, the traditional ampoule bottle is commonly used for storing medicines for injection, vaccines, serum and the like, and is also used for packaging oral liquid. Along with the development of manufacturing industry, plastic ampoule bottle has appeared nowadays, and because the ductility of material is high, can not produce the piece when breaking, can overcome the shortcoming of glass ampoule bottle. In the current plastic ampoule bottle production line, when the plastic ampoule bottle is produced, in order to improve production efficiency, a plurality of ampoule bottles are generally produced in a connected mode to form the plastic ampoule bottles in a row, the production speed is high, the yield is large, and therefore the current ampoule bottle conveying mechanism is generally closely conveyed in a mode that the ampoule bottles are attached to each other front and back. Although the transportation space can be saved in such a transportation mode, the problem that the gaps among the plastic ampoules in the row are small, the plastic ampoules in the row are difficult to mark on a visual detection line, and the visual detection of the plastic ampoules in the row is inconvenient and comprehensive.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a conveying mechanism for plastic ampoules, which aims to solve the problems that in the existing conveying process, gaps among rows of plastic ampoules are small, the rows of plastic ampoules are difficult to mark on a visual detection line, and the rows of plastic ampoules are inconvenient to be comprehensively visually detected.

In order to solve the technical problems, the utility model discloses: a conveying mechanism for plastic ampoule bottles comprises a first conveying section, a second conveying section, an intercepting cylinder, a slide way, a pushing assembly and a stopping assembly;

the terminal end of the first transportation section is connected with the starting end of the second transportation section; the terminal end of the second transportation section is connected with the starting end of the slideway, and the transportation speed of the second transportation section is greater than that of the first transportation section;

the intercepting cylinder is arranged on one side of the terminal of the first transportation section, and the movable end of the intercepting cylinder extends out towards the other side of the terminal of the first transportation section;

the terminal end of the second transportation section is connected with the starting end of the slideway; the pushing assembly is used for pushing the row of plastic ampoule bottles on the slideway to move to the terminal of the slideway one by one; the stopping assembly is used for stopping the plastic ampoule bottles in the row at the terminal of the slide way.

As an alternative embodiment, the pushing assembly comprises a pushing member and a turning portion; the pushing piece is in transmission connection with the rotating portion, and the rotating portion is used for driving the pushing piece to push the row of plastic ampoule bottles from the initial end of the slide way to the terminal end of the slide way and rotating the pushing piece to the initial end of the slide way.

As an alternative embodiment, the turning part comprises a turning belt, an auxiliary side plate and a first driving member;

the auxiliary side plate is vertically arranged on one side of the slide way, and the length direction of the auxiliary side plate is parallel to the length direction of the slide way;

the rotary belt is horizontally and rotatably arranged on the same side of the slide way provided with the auxiliary side plate, and part of the inner side surface of the rotary belt is attached to a side surface plate of the auxiliary side plate close to the slide way;

the first driving piece is used for driving the rotary belt to rotate;

the plurality of pushing pieces are mounted on the rotating belt at equal intervals.

As an alternative embodiment, the pushing member is L-shaped, and the corner of the pushing member is horizontally and rotatably arranged on the top surface of the revolving belt;

the top surface of the auxiliary side plate is higher than the top surface of the rotary belt;

the first driving piece comprises a first driving wheel and a second driving wheel, the first driving wheel is arranged behind the auxiliary side plate, the second driving wheel is arranged in front of the auxiliary side plate, the first driving wheel and the second driving wheel are respectively in transmission connection with a rotary belt, and a steering gap is formed between the second driving wheel and the auxiliary side plate;

the first driving wheel is provided with a steering roller wheel, the steering roller wheel is rotatably arranged at the top of the first driving wheel, and the top surface of the steering roller wheel is higher than that of the rotary belt.

As an alternative embodiment, the stop assembly comprises a stop block and a second driving piece;

the stop block is movably arranged at the terminal of the slide way;

the second driving piece is used for driving the stop block to move so that the stop block blocks and opens the terminal of the slide way.

As an optional implementation manner, the second driving member includes a connecting rod and a cam driving portion, the middle portion of the connecting rod is vertically and rotatably connected below the slideway, and the cam driving portion is arranged below the slideway; the stop block is fixedly arranged at the rear end of the connecting rod, and the front end of the connecting rod is in transmission connection with the cam driving part to form a cam mechanism.

As an alternative embodiment, the pushing assembly is provided with a cover plate which is covered on the top of the turning part.

As an alternative embodiment, the first transport section, the second transport section and the chute are provided with guide rods on both sides.

Compared with the prior art, the embodiment of the utility model has the following beneficial effects:

in an embodiment of the utility model, the differential transport is achieved by designing the transport speed of the second transport section to be greater than the transport speed of the first transport section. Therefore, when the row of plastic ampoule bottles positioned at the tail end of the first transportation section contacts the second transportation section, the forward transportation speed of the row of plastic ampoule bottles is higher than that of other row of plastic ampoule bottles positioned on the first transportation section, the distance between the row of plastic ampoule bottles and the next row of plastic ampoule bottles is increased, the row of plastic ampoule bottles which are continuously transported are converted into transportation at regular intervals one by one, and the assembly is pushed to push the row of plastic ampoule bottles on the slideway to move to the terminal of the slideway. The utility model is applied to a visual inspection line, and the row of plastic ampoules are regularly transported one by one at intervals, so that the marking of each row of plastic ampoules is facilitated, and the visual inspection of the row of plastic ampoules is conveniently and comprehensively carried out.

The intercepting cylinder is used for intercepting and releasing the row of plastic ampoules at the terminal of the first transportation section. Specifically, at first, the intercepting cylinder stretches out its expansion end to the inline plastics ampoule at interception first transportation district section terminal, makes the inline plastics ampoule can not enter into the second transportation district section, and when pushing assembly can promote next inline plastics ampoule, the intercepting cylinder withdraws its expansion end, in order to let pass the inline plastics ampoule at first transportation district section terminal, the inline plastics ampoule who is let pass then can be transported forward with higher speed under the drive of second transportation district section, in order to realize pulling open the interval with the next inline plastics ampoule. And after the released row of plastic ampoule bottles completely pass through the intercepting cylinder, the intercepting cylinder extends out of the movable end of the intercepting cylinder again to intercept one row of plastic ampoule bottles. The circulation is carried out, so that the row of plastic ampoule bottles can be transported to the slideway one by one regularly at intervals in a production line for high-speed transportation.

It should be noted that, in this embodiment, the pushing assembly pushes the rows of plastic ampoules on the slide one by one, and the stopping assembly is used to stop at the terminal of the slide, so as to achieve the effect that the rows of plastic ampoules are placed at the terminal of the slide, and facilitate the subsequent handling and transportation of the rows of plastic ampoules. For example, when the row of plastic ampoules is placed at the end of the slide way, the row of plastic ampoules can be conveniently subjected to image acquisition or clamped for carrying.

Drawings

FIG. 1 is a schematic structural diagram of one embodiment of the present invention;

FIG. 2 is a schematic diagram of a pushing assembly according to one embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a stop assembly according to one embodiment of the present invention;

FIG. 4 is a schematic structural diagram of another embodiment of the present invention;

in the drawings: 100-first transport section, 200-second transport section, 300-slideway, 400-pushing assembly, 410-pushing member, 420-revolving part, 421-revolving belt, 422-auxiliary side plate, 423-turning notch, 424-first driving member, 425-first driving wheel, 426-turning roller, 427-second driving wheel, 500-stopping assembly, 510-stopping block, 520-second driving member, 521-connecting rod, 522-cam driving part, 600-intercepting cylinder, 700-cover plate and 800-guide rod.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used merely for convenience of description and for simplicity of description, and do not indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Furthermore, features defined as "first" and "second" may explicitly or implicitly include one or more of the features for distinguishing between descriptive features, non-sequential, non-trivial and non-trivial.

With reference to fig. 1 to 4, a transportation mechanism for plastic ampoules according to an embodiment of the present invention is described, which includes a first transportation section 100, a second transportation section 200, a slide 300, a pushing assembly 400, a stop assembly 500, and an intercepting cylinder 600; the terminal end of the first transport section 100 is contiguous with the beginning of the second transport section 200; the end of the second transportation section 200 is connected with the beginning of the chute 300, and the transportation speed of the second transportation section 200 is greater than that of the first transportation section 100; the spacing between the rows of plastic ampoules is increased to achieve the spaced transportation of the rows of plastic ampoules, for example, the first transportation section 100 has a transportation speed of 1m/s and the second transportation section 200 has a transportation speed of 2 m/s. The end of the second transport section 200 is contiguous with the beginning of the chute 300; the pushing assembly 400 is used for pushing the rows of plastic ampoules on the slide 300 to move to the terminal end of the slide 300 one by one; the stop assembly 500 is used to stop the inline plastic ampoules at the end of the slide 300.

Specifically, in the present invention, for the sake of convenience of description and understanding, the moving direction of the row of plastic ampoules is defined as the front, and the rear and the left and right sides of the row of plastic ampoules are sequentially determined. More specifically, as shown in fig. 1, in one preferred embodiment, the first transport section 100 and the second transport section 200 may each be a belt transport mechanism and each transport inline plastic ampoules along the front.

In an embodiment of the present invention, differential transport is achieved by designing the transport speed of the second transport section 200 to be greater than the transport speed of the first transport section 100. In this way, when the row of plastic ampoules located at the end of the first transportation section 100 contacts the second transportation section 200, the row of plastic ampoules is transported forward at a higher speed than the other rows of plastic ampoules located at the first transportation section 100, and the distance between the row of plastic ampoules and the next row of plastic ampoules is increased, so that the sequential row of plastic ampoules is converted into the interval transportation. So as to facilitate the pushing assembly 400 to push the plastic ampoules in the row on the slide 300 to move to the terminal end of the slide 300.

Wherein the intercept cylinder 600 is used to intercept and clear the inline plastic ampoules at the end of the first transport section 100. Specifically, first, the intercepting cylinder 600 extends out of the movable end thereof to intercept the lined plastic ampoules at the terminal of the first transportation section 100, so that the lined plastic ampoules cannot enter the second transportation section 200, and when the pushing assembly 400 can push the next lined plastic ampoule, the intercepting cylinder 600 retracts into the movable end thereof to release the lined plastic ampoules at the terminal of the first transportation section 100, and the released lined plastic ampoules are accelerated to be transported forward under the driving of the second transportation section 200, so that the spacing is pulled away from the next lined plastic ampoule. When the released row of plastic ampoule bottles completely passes through the intercepting cylinder 600, the intercepting cylinder 600 extends out of the movable end of the intercepting cylinder again to intercept the released row of plastic ampoule bottles. The plastic ampoule bottles in the row are regularly and alternately transported to the slideway 300 one by one in such a circulating way.

It should be noted that, in this embodiment, the pushing assembly 400 pushes the rows of plastic ampoules on the slide 300 one by one, and the stopping assembly 500 is used to stop at the terminal of the slide 300, so as to achieve the effect that the rows of plastic ampoules are placed at the terminal of the slide 300, and facilitate the subsequent handling and transportation of the rows of plastic ampoules. For example, when the row of plastic ampoules is standing at the end of the slide 300, the row of plastic ampoules can be conveniently subjected to image acquisition or clamped for carrying.

As an alternative embodiment, the pushing assembly 400 includes a pushing member 410 and a turning portion 420; the pushing member 410 is in transmission connection with the rotating portion 420, and the rotating portion 420 is used for driving the pushing member 410 to push the plastic ampoule bottle in the row from the starting end of the slide 300 to the terminal end of the slide 300, and for rotating the pushing member 410 to the starting end of the slide 300.

In this embodiment, the rotation portion 420 is used to drive the pushing member 410 to rotate, so that the pushing member 410 pushes the row of plastic ampoules from the beginning of the slide 300 to the end of the slide 300 and then rotates to the beginning of the slide 300 to push the next row of plastic ampoules. The continuity of pushing away the material is high, and does benefit to setting up a plurality of pushing pieces 410 and promote the antithetical couplet row plastics ampoule on the slide 300 one by one according to the preface, and the treatment effeciency is high to do benefit to and use in the visual inspection of high-speed antithetical couplet row plastics ampoule produces the line.

As an alternative embodiment, the turning part 420 includes a turning belt 421, an auxiliary side plate 422, and a first driving member 424; the auxiliary side plate 422 is vertically arranged on one side of the slideway 300, and the length direction of the auxiliary side plate 422 is parallel to the length direction of the slideway 300; the rotary belt 421 is horizontally and rotatably arranged on the same side of the slide 300 with the auxiliary side plate 422, and part of the inner side surface of the rotary belt 421 is attached to one side plate of the auxiliary side plate 422 close to the slide 300; the first driving member 424 is used for driving the revolving belt 421 to revolve; a plurality of the pushing members 410 are installed on the rotary belt 421 at equal intervals.

In this embodiment, a part of the inner side surface of the rotary belt 421 is attached to a side surface plate of the auxiliary side plate 422 close to the slide 300, so as to ensure that a local section of the rotary belt 421 can be transported forward parallel to the slide 300 during rotation, and thus, the pushing member 410 can be arranged on the outer ring of the rotary belt 421, so that not only can the pushing member 410 horizontally rotate, but also the pushing member 410 can effectively push the plastic ampoules in a row along the length direction of the slide 300.

As an alternative embodiment, the pushing member 410 is L-shaped, and the corner of the pushing member 410 is horizontally and rotatably disposed on the top surface of the revolving belt 421; the top surface of the auxiliary side plate 422 is higher than the top surface of the rotary belt 421; the first driving member 424 comprises a first driving wheel 425 and a second driving wheel 427, and the first driving wheel 425 or the second driving wheel 427 is driven to rotate by a motor; the first driving wheel 425 is arranged behind the auxiliary side plate 422, the second driving wheel 427 is arranged in front of the auxiliary side plate 422, the first driving wheel 425 and the second driving wheel 427 are respectively in transmission connection with the rotary belt 421, and a steering gap 423 is arranged between the second driving wheel 427 and the auxiliary side plate 422; a steering roller 426 is arranged on the first driving wheel 425, the steering roller 426 is rotatably arranged at the top of the first driving wheel, and the top surface of the steering roller 426 is higher than the top surface of the rotary belt 421.

More specifically, as shown in the embodiment of fig. 2, when the pushing member 410 pushes the plastic ampoules in the row, one straight edge of the pushing member 410 abuts against the portion of the auxiliary side plate 422 higher than the rotating belt 421, and the other straight edge of the pushing member 410 is located in the sliding channel 300 and abuts against the rear wall of the plastic ampoules in the row. When the plastic ampoule bottles in the row reach the terminal of the slide 300, the pushing member 410 is located at the turning notch 423, and due to the arrangement of the stopping assembly 500, the plastic ampoule bottles in the row are stopped at the terminal of the slide 300, at this time, based on the reaction force of the plastic ampoule bottles in the row and the forward power of the rotary belt 421, the pushing member 410 rotates at the turning notch 423, so that a straight edge pushing the plastic ampoule bottles in the row originally in the slide 300 rotates backwards and leaves the slide 300, and the rotary belt 421 can normally rotate. Further, when the pushing member 410 is about to rotate to the front end of the slide 300, that is, when the pushing member 410 rotates around the first driving wheel 425, the rotating roller 426 abuts against a straight edge of the pushing member 410, so that the pushing member 410 rotates again relative to the rotating belt 421, the straight edge for pushing the plastic ampoule bottle in the row is reentered into the slide 300, and the other straight edge abuts against a part of the auxiliary side plate 422 higher than the rotating belt 421. The structure is ingenious, and the technical problem that the pushing piece 410 is prevented from rotating due to the arrangement of the stop component 500 is effectively solved. When the pushing member 410 is used to push a straight edge of the row of plastic ampoules to reenter the slide 300, the pushing member 410 is located between the row of plastic ampoules at the beginning of the slide 300 and the front-most row of plastic ampoules on the second transportation section 200.

As an alternative embodiment, the stop assembly 500 includes a stop block 510 and a second driver 520; the stopper 510 is movably arranged at the terminal end of the slideway 300; the second driving member 520 is used to drive the stopper 510 to move, so that the stopper 510 blocks and opens the terminal end of the slide 300.

Specifically, the second actuator 520 may be a second cylinder, and a telescopic end of the second cylinder is connected to the stopper 510 such that the stopper 510 blocks and opens the terminal end of the chute 300. Utilize second cylinder drive dog 510 to appear at the terminal of slide 300, reach and hinder the antithetical couplet row plastics ampoule and continue to move forward, reduce the translation rate of antithetical couplet row plastics ampoule simultaneously. When the row of plastics ampoule at slide 300 terminal need shift, second driving piece 520 drive dog 510 shift out the slide 300 the terminal can, make row of plastics ampoule can the level shift out slide 300, need not to mention row of plastics ampoule, do benefit to beat production control and do benefit to and improve conveying efficiency.

As an alternative embodiment, the second driving element 520 includes a link 521 and a cam driving part 522, the middle part of the link 521 is vertically and rotatably connected below the slideway 300, and the cam driving part 522 is arranged below the slideway 300; the stopper 510 is fixedly disposed at the rear end of the link 521, and the front end of the link 521 is in transmission connection with the cam driving part 522 to form a cam mechanism.

As shown in the embodiment of fig. 3, the cam driving part 522 includes a motor and a cam, and the motor rotates the cam. The front end of the link 521 is connected with the outer periphery of the cam in a rolling manner, when the front end of the link 521 abuts against the convex part of the cam, the front end of the link 521 sinks, and the rear end of the link 521 is lifted, so that the stopper 510 is driven to appear at the terminal end of the slide 300. When the front end of the link 521 abuts against the rest of the cam, the front end of the link 521 is raised, and the rear end of the link 521 sinks, so as to drive the stopper 510 to sink away from the terminal of the slide 300, thereby opening the terminal of the slide 300.

As an alternative embodiment, the pushing assembly 400 is provided with a cover plate 700, and the cover plate 700 is covered on the top of the turning part 420.

In this embodiment, cover through the apron 700 and establish at the top of gyration portion 420, realize enclosing and cover gyration portion 420 to avoid workman's touching gyration portion 420 and the production accident appears, and avoid debris to drop and hinder gyration portion 420 gyration, reach the effect of production safety and high-efficient production.

As an alternative embodiment, guide rods 800 are respectively disposed at two sides of the first transportation section 100, the second transportation section 200 and the chute 300. Specifically, as shown in fig. 3, the guide rod 800 is used as a limiting wall to support the transportation of the plastic ampoule bottles in the row, so that the plastic ampoule bottles in the row are prevented from inclining and falling down, even falling out of the transportation mechanism, and the orderly transportation of the plastic ampoule bottles in the row is realized, thereby improving the transportation efficiency.

Other constructions and operation of a plastic ampoule transport mechanism according to embodiments of the present invention are known to those of ordinary skill in the art and will not be described in detail herein.

In the description herein, references to the description of the terms "embodiment," "example," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the utility model have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the utility model, the scope of which is defined by the claims and their equivalents.

Claims

1. The utility model provides a transport mechanism of plastics ampoule which characterized in that: the device comprises a first transportation section, a second transportation section, a slide way, an intercepting cylinder, a pushing assembly and a stopping assembly;

2. The transport mechanism for plastic ampoules according to claim 1, wherein: the pushing assembly comprises a pushing piece and a rotary part; the pushing piece is in transmission connection with the rotating portion, and the rotating portion is used for driving the pushing piece to push the row of plastic ampoule bottles from the initial end of the slide way to the terminal end of the slide way and rotating the pushing piece to the initial end of the slide way.

3. The transport mechanism for plastic ampoules according to claim 2, wherein: the rotary part comprises a rotary belt, an auxiliary side plate and a first driving piece;

the first driving piece is used for driving the rotary belt to rotate;

4. A transport mechanism for plastic ampoules according to claim 3, wherein:

the pushing piece is L-shaped, and the corner of the pushing piece is horizontally and rotatably arranged on the top surface of the rotary belt;

5. The transport mechanism for plastic ampoules according to claim 2, wherein: the stop assembly comprises a stop block and a second driving piece;

the stop block is movably arranged at the terminal of the slide way;

6. The transport mechanism for plastic ampoules according to claim 5, wherein: the second driving piece comprises a connecting rod and a cam driving part, the middle part of the connecting rod is vertically and rotatably connected below the slideway, and the cam driving part is arranged below the slideway; the stop block is fixedly arranged at the rear end of the connecting rod, and the front end of the connecting rod is in transmission connection with the cam driving part to form a cam mechanism.

7. The transportation mechanism of claim 6, wherein the pushing assembly is provided with a cover plate, and the cover plate is covered on the top of the turning part.

8. The transport mechanism for plastic ampoules according to claim 1, wherein: guide rods are respectively arranged on two sides of the first transportation section, the second transportation section and the slide way.