CN214454676U - A high-efficient pay-off structure for in bottle lid is sealed - Google Patents

Abstract

The utility model provides a high-efficient pay-off structure for bottle lid is sealed, include the conveyer belt and be located the limiting plate of conveyer belt both sides, the one end level of conveyer belt is provided with the cab apron, cross the top of cab apron with the top of conveyer belt is high, just cross the tip of cab apron with set for the clearance has between the tip of conveyer belt, the one side of crossing the cab apron is provided with the deflector that is the slope form, just the bottom of deflector with cross the cab apron and connect, the upper surface of deflector is vertical to be provided with a plurality of guide board, arbitrary adjacent two form the guide space between the guide board, cross the cab apron and deviate from the vertical termination board that is provided with in one side of deflector, the one end that terminates the board is just to one the limiting plate. The utility model provides a pair of a high-efficient pay-off structure for in bottle lid is sealed can improve production efficiency.

Description

A high-efficient pay-off structure for in bottle lid is sealed

Technical Field

The utility model belongs to the technical field of plastic bottle processing, a high-efficient pay-off structure for in bottle lid is sealed is related to.

Background

The plastic bottle is a bottle made of plastic materials as the name implies, and mainly comprises a bottle body and a bottle cap matched with the bottle body, wherein some objects need to be well protected, such as food, medicine and the like, at the moment, a protective layer needs to be arranged at the bottle opening of the bottle body, and the protective layer is connected with the bottle opening in a sealing manner, so that the sealing effect is realized.

At present, there is one kind in the market to the realization connected mode between inoxidizing coating and the bottleneck for the heat-seal, and the equipment name that realizes the heat-seal is the heat-sealer, and its concrete principle is: by utilizing the principle of electromagnetic induction, namely, an eddy magnetic field is generated when electromagnetism is contacted with a metal substance, an aluminum foil (namely a protective layer) on the bottle mouth instantly generates high heat, and then the aluminum foil is fused on the bottle mouth, so that the function of sealing is achieved.

Wherein, the bottles are usually arranged on a conveyor belt to be naturally driven, the bottles are heat-sealed when moving to the bottom of a hot air blower, and meanwhile, in order to prevent the bottles from falling off the conveyor belt, guard rails or guard plates are usually arranged on both sides of the conveyor belt, so that each operation needs workers to independently put the bottles between the guard rails or the guard plates arranged on both sides oppositely, and furthermore, in order to accelerate the production efficiency, some factories and trades can produce the conveyor belt into a longer length, so that the workers can place the bottles on one side or both sides simultaneously, but the operators at the upstream need to observe and pay attention not to touch or knock down the bottles at the upstream when the bottles are placed at the downstream, the observation and judgment takes some time, and the bottles at the upstream also reduce the space for placing the bottles at the downstream, the difficulty of placing the bottles is increased, so that the efficiency is often lower in the actual production.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient pay-off structure for in bottle lid is sealed, aim at solving the problem that production efficiency is low.

For solving the technical problem, the utility model provides a high-efficient pay-off structure for bottle lid is sealed, include the conveyer belt and be located the limiting plate of conveyer belt both sides, the one end level of conveyer belt is provided with the cab apron, cross the cab apron the top with the top of conveyer belt is equal high, just cross the tip of cab apron with set for the clearance has between the tip of conveyer belt, the one side of crossing the cab apron is provided with the deflector that is the slope form, just the bottom of deflector with cross the cab apron and connect, the vertical a plurality of guide board that is provided with of upper surface of deflector, arbitrary adjacent two form the guide space between the guide board, cross the cab apron and deviate from the vertical termination board that is provided with in one side of deflector, the one end of termination board is just to one the limiting plate.

The utility model discloses further set up to, the upper surface activity laminating of crossing the cab apron is provided with the slurcam, one side activity laminating of slurcam in the end board, the opposite side with set for the distance between the bottom of guide board has.

The utility model discloses further set up to, cross the cab apron and deviate from one side level of conveyer belt is provided with the supporting part that the longitudinal section is L shape, be provided with the stabilizing part that the longitudinal section is L shape on the slurcam, the bottom activity of stabilizing part laminate in cross the top of cab apron or the bottom of supporting part, the lateral part activity of stabilizing part laminate in the lateral part of supporting part, and be used for the shutoff guide space's bottom.

The utility model discloses further set up to, the stable hole has been seted up to the middle part level of termination board, the lateral part of slurcam is provided with the activity and is located connecting portion in the stable hole, be provided with anticreep portion on the connecting portion, anticreep portion activity laminate in the termination board deviates from one side of slurcam, just the diameter of anticreep portion is greater than the width of stable hole.

The utility model discloses further set up to, the vertical action bars that is provided with of upper surface of stabilization part bottom, the top of action bars is higher than the top of termination board and the supporting part with the top of stabilization part.

The utility model discloses further set up to, the action bars with the stabilizing part rotates to be connected.

The utility model discloses further set up to, the supporting part deviates from the tip inner wall of conveyer belt is provided with the anticreep arch, works as connecting portion conflict in the stabilizer hole deviates from during the tip of conveyer belt, the stabilizer conflict in the anticreep is protruding.

The utility model discloses further set up as, the thickness at guide board top is less than the thickness of bottom, the opening at guide space top is greater than the opening of bottom.

The utility model discloses further set up to, two be provided with two drive shafts between the limiting plate and be located two supporter between the drive shaft, the drive shaft with the limiting plate rotates to be connected, just the both ends of conveyer belt cup joint respectively in two the drive shaft is located the upside the lower surface activity of conveyer belt laminate in the upper surface of supporter, the supporter is close to convex first cooperation groove has been seted up to the one end of drive shaft, cross the cab apron and be close to convex second cooperation groove has been seted up to the one end of conveyer belt, the inner wall in first cooperation groove with between the outer wall of drive shaft and the inner wall in second cooperation groove with all have between the outer wall of conveyer belt and set for the interval.

Compared with the prior art, the utility model provides a high-efficient pay-off structure for in bottle lid is sealed, when carrying out the heat-seal, the workman preferably stands in the top position of deflector simultaneously for a plurality of at first, then a workman puts into the bottle towards the top in one or two or more guide spaces; then the bottles slide down from the bottoms of the guide plates to the transition plates under the action of gravity and the guide action of the guide plates, and finally are blocked by the stop plates so as not to move continuously; the worker then pushes the row of bottles from the transition plate onto a conveyor belt via a pusher plate, and the conveyor belt rotates (driven by a motor) to move the bottles to the bottom of the heat sealer for heat sealing.

When the worker places the bottles into the guide spaces, because each guide space is independent and does not interfere with each other, the worker can judge whether the placed bottles can act on the bottles on the upstream or not in the actual operation process, and only the bottles need to be placed at the same time, the bottles on the upstream can be stopped or blocked by the bottles on the downstream, so that the processing efficiency is improved from the side.

It should be understood that the construction and principles of the heat sealer are well known and remote and do not affect the understanding of the art claimed herein by those skilled in the art, if not addressed, and that the actual construction to be protected is a feed construction used in conjunction with the heat sealer and therefore the heat sealer may not be addressed or described in detail.

Drawings

Fig. 1 is a first structural schematic view of an embodiment of a high-efficiency feeding structure for bottle cap sealing according to the present invention;

FIG. 2 is an enlarged view of portion A of FIG. 1;

fig. 3 is a schematic structural diagram of an embodiment of a high-efficiency feeding structure for bottle cap sealing according to the present invention;

FIG. 4 is an enlarged view of portion B of FIG. 3;

FIG. 5 is an enlarged view of portion C of FIG. 3;

fig. 6 is a cross-sectional view of an embodiment of a high efficiency feeding structure for use in bottle cap sealing according to the present invention;

FIG. 7 is an enlarged view of portion D of FIG. 6;

fig. 8 is a schematic structural view of an embodiment of a guide plate and a guide plate in a high-efficiency feeding structure for bottle cap sealing according to the present invention.

Wherein, 1, a conveyer belt; 2. a limiting plate; 3. a transition plate; 4. a guide plate; 5. a guide plate; 6. a guide space; 7. a termination plate; 8. a push plate; 9. a support portion; 10. a stabilizer; 11. a stabilization well; 12. a connecting portion; 13. an anti-drop part; 14. an operating lever; 15. the anti-drop bulge; 16. a drive shaft; 17. a support body; 18. a first mating groove; 19. a second mating groove.

Detailed Description

The following describes a high-efficiency feeding structure for bottle cap sealing according to the present invention in detail with reference to the accompanying drawings and specific embodiments. The advantages and features of the present invention will become more apparent from the following description. It should be noted that the drawings are in simplified form and are not to precise scale, and are provided for convenience and clarity in order to facilitate the description of the embodiments of the present invention. The same or similar reference numbers in the drawings identify the same or similar elements.

The utility model provides a high-efficient pay-off structure for bottle lid is sealed, as shown in fig. 1 to 8, include conveyer belt 1 and be located the limiting plate 2 of 1 both sides of conveyer belt, the one end level of conveyer belt 1 is provided with cab apron 3, cross cab apron 3 the top with the top of conveyer belt 1 is equal high, just cross cab apron 3 the tip with set for the clearance has between the tip of conveyer belt 1, the one side of crossing cab apron 3 is provided with deflector 4 that is the slope form, just the bottom of deflector 4 with cross cab apron 3 and connect, the vertical a plurality of guide board 5 that is provided with of upper surface of deflector 4, arbitrary adjacent two form guide space 6 between the guide board 5, cross cab apron 3 and deviate from the vertical termination board 7 that is provided with in one side of deflector 4, the one end that terminates board 7 is just to one limiting plate 2.

The upper surface of the transition plate 3 is movably jointed with a pushing plate 8, one side of the pushing plate 8 is movably jointed with the terminating plate 7, and the other side of the pushing plate is provided with a set distance from the bottom of the guide plate 5. One side of the transition plate 3, which is far away from the conveying belt 1, is horizontally provided with a supporting part 9 with an L-shaped longitudinal section, a stabilizing part 10 with an L-shaped longitudinal section is arranged on the pushing plate 8, the bottom of the stabilizing part 10 is movably attached to the top of the transition plate 3 or the bottom of the supporting part 9, and the lateral part of the stabilizing part 10 is movably attached to the lateral part of the supporting part 9 and used for plugging the bottom of the guide space 6.

Stability hole 11 has been seted up to the middle part level of terminating board 7, the lateral part of slurcam 8 is provided with the activity and is located connecting portion 12 in the stability hole 11, be provided with anticreep portion 13 on connecting portion 12, anticreep portion 13 activity laminate in terminating board 7 deviates from one side of slurcam 8, just the diameter of anticreep portion 13 is greater than the width of stability hole 11.

An operating rod 14 is vertically arranged on the upper surface of the bottom of the stabilizer 10, and the top of the operating rod 14 is higher than the top of the terminating plate 7 and the tops of the supporting part 9 and the stabilizer 10. The operating lever 14 is rotatably connected to the stabilizer 10. Supporting part 9 deviates from the tip inner wall of conveyer belt 1 is provided with anticreep arch 15, works as connecting portion 12 contradict in stabilizer hole 11 deviates from during the tip of conveyer belt 1, stabilizer 10 contradicts in anticreep arch 15.

The thickness of the top of the guide plate 5 is smaller than that of the bottom, and the opening of the top of the guide space 6 is larger than that of the bottom. Two be provided with two drive shafts 16 between the limiting plate 2 and be located two supporter 17 between the drive shaft 16, drive shaft 16 with limiting plate 2 rotates to be connected, just the both ends of conveyer belt 1 cup joint respectively in two drive shaft 16 is located the upside the lower surface activity of conveyer belt 1 laminate in supporter 17's upper surface, supporter 17 is close to convex first cooperation groove 18 has been seted up to the one end of drive shaft 16, it is close to cross cab apron 3 convex second cooperation groove 19 has been seted up to the one end of conveyer belt 1, the inner wall of first cooperation groove 18 with between the outer wall of drive shaft 16 and the inner wall of second cooperation groove 19 with all have between the outer wall of conveyer belt 1 and set for the interval.

The utility model provides a high-efficient pay-off structure for in bottle lid is sealed, when carrying out the heat-seal, the workman preferably a plurality of stands simultaneously in the top position of deflector 4 at first, then a workman puts into the bottle towards the top of one or two or more guide spaces 6; then, the bottles slide down from the bottom of the guide plate 4 to the transition plate 3 under the action of gravity and the guide of the guide plate 5, and finally are blocked by the stop plate 7 so as not to move continuously, and meanwhile, the subsequent bottles are blocked by the front bottles so as not to move continuously; the worker then pushes a row of bottles from the transition plate 3 onto the conveyor belt 1 by means of the push plate 8, and the conveyor belt 1 rotates (driven by a motor) so that the bottles move to the bottom of the heat sealing machine for heat sealing.

When a worker places bottles into the guide spaces 6, because each guide space 6 is independent and does not interfere with each other, the worker can judge whether the placed bottles can act with the bottles on the upstream in the actual operation process, and only needs to place the bottles on the upstream without considering that the bottles on the downstream can be blocked or blocked, so that the processing efficiency is improved from the side.

It should be understood that the construction and principles of the heat sealer are well known and remote and do not affect the understanding of the art claimed herein by those skilled in the art, if not addressed, and that the actual construction to be protected is a feed construction used in conjunction with the heat sealer and therefore the heat sealer may not be addressed or described in detail.

In actual use, only a space slightly larger than the diameter of the bottles is left on the conveying belt 1 and the transition plate 3, so that only one row of bottles can be conveyed onto the conveying belt 1 at each time, in the conveying process, a worker holds the operating rod 14 by hand, then pushes the push plate 8 to move towards the conveying belt 1 through the operating rod 14, and in the process, the bottles on the transition plate 3 are all pushed onto the conveying belt 1 (the gap between the conveying belt 1 and the transition plate 3 is small, so that the bottles can be directly pushed up), and meanwhile, the vertical structure part of the stabilizing part 10 blocks the bottom of the guide space 6, so that subsequent bottles can be prevented from continuously descending onto the transition plate 3; after the row of bottles is pushed onto the conveyer belt 1, the pushing plate 8 is moved in the opposite direction, and in the process that the stabilizing part 10 is pulled out from the transition plate 3, the bottles fall onto the transition plate 3 one by one, so that the next pushing process can be continued.

Wherein, in this promotion process, the bottom of slurcam 8 is laminated on cab apron 3 or supporting part 9 through stabiliser 10, and the horizontal direction has received anticreep portion 13 and the spacing of termination board 7, so the position of stabiliser 10 and slurcam 8 can be stable keeps, and this in-process, can be so that slurcam 8 and stabiliser 10 all keep less clearance with between the bottom of guide board 5, prevented that the structure from colliding, simultaneously also can be fine prevent that the bottle from landing by oneself. In the process of driving the stabilizer 10 to reciprocate by the operating lever 14, the operating lever 14 does not rotate relative to the hand of the operator, but rotates relative to the stabilizer 10 only, so that the operating comfort can be improved.

In the use, when connecting portion 12 contradicts the tip of stabilizing hole 11, on stabilizing portion 10 has also contradicted anticreep arch 15, not only can prevent like this that stabilizing portion 10 and slurcam 8 from crossing cab apron 3 and supporting part 9 landing, can also disperse workman's effort simultaneously, prevent that connecting portion 12 from taking place deformation.

The guide plate 5 has a smaller top thickness and a larger bottom thickness, thus making the opening at the top of the guide space 6 larger for the worker to insert the bottle, while the opening at the bottom is smaller and slightly larger than the diameter of the bottle, thus allowing one bottle to pass through at a time and also preventing the bottle from jamming at the bottom.

In the moving process of the bottles, the weight of the bottles is mainly transferred to the supporting body 17 through the conveying belt 1 to bear, so that the conveying belt 1 is protected; at the same time, the first and second matching grooves 18, 19 have a small clearance with the drive shaft 16 and the conveyor belt 1, respectively, so that the bottles are supported better and the bottles are transferred more easily.

In a further embodiment, the guide plate 4 is connected to the side of the limiting plate 2, so that the bottles can fall down from the guide plate 4 to the conveyer belt 1, and thus, although the bottles can be transferred to the conveyer belt 1 without operating the pushing plate 8, the bottles at the upstream side are easy to be jammed with the bottles at the downstream side in the method, namely, the bottles at the upstream side, the bottles at the downstream side and the guide plate 5 at the downstream side are jammed, and the bottles cannot be transported continuously; but this stabilization is not present if by pushing the plate 8, the stabilizers 10, so that the bottles can be stably conveyed.

It should be noted that, in the present specification, the embodiments are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments may be referred to each other.

The above description is only for the preferred embodiment of the present invention and is not intended to limit the scope of the present invention, and any modification and modification made by those skilled in the art according to the above disclosure are all within the scope of the claims.

Claims (9)

1. The efficient feeding structure for bottle cap sealing is characterized by comprising a conveying belt (1) and limiting plates (2) located on two sides of the conveying belt (1), wherein a transition plate (3) is horizontally arranged at one end of the conveying belt (1), the top of the transition plate (3) is as high as the top of the conveying belt (1), a set gap is formed between the end of the transition plate (3) and the end of the conveying belt (1), an inclined guide plate (4) is arranged on one side of the transition plate (3), the bottom of the guide plate (4) is connected with the transition plate (3), a plurality of guide plates (5) are vertically arranged on the upper surface of the guide plate (4), a guide space (6) is formed between any two adjacent guide plates (5), and a stop plate (7) is vertically arranged on one side of the transition plate (3) far away from the guide plate (4), one end of the termination plate (7) is right opposite to the limiting plate (2).

2. The feeding structure of claim 1, wherein the transition plate (3) is movably attached to the upper surface thereof with a pushing plate (8), one side of the pushing plate (8) is movably attached to the terminating plate (7), and the other side of the pushing plate is spaced from the bottom of the guide plate (5) by a predetermined distance.

3. The feeding structure for bottle cap sealing of claim 2, wherein a support part (9) with an L-shaped longitudinal section is horizontally arranged on one side of the transition plate (3) departing from the conveyor belt (1), a stabilizer (10) with an L-shaped longitudinal section is arranged on the pushing plate (8), the bottom of the stabilizer (10) is movably attached to the top of the transition plate (3) or the bottom of the support part (9), and the side of the stabilizer (10) is movably attached to the side of the support part (9) and used for sealing the bottom of the guiding space (6).

4. The efficient feeding structure for bottle cap sealing according to claim 3, wherein a stabilizing hole (11) is horizontally formed in the middle of the terminating plate (7), a connecting portion (12) movably located in the stabilizing hole (11) is arranged on the side portion of the pushing plate (8), an anti-dropping portion (13) is arranged on the connecting portion (12), the anti-dropping portion (13) is movably attached to one side of the terminating plate (7) departing from the pushing plate (8), and the diameter of the anti-dropping portion (13) is greater than the width of the stabilizing hole (11).

5. A high efficiency feeding structure for use in bottle cap seal according to claim 3 characterized in that the upper surface of the stabilizer (10) bottom is vertically provided with an operating rod (14), the top of the operating rod (14) is higher than the top of the terminating plate (7) and the top of the support part (9) and the stabilizer (10).

6. A feeding mechanism for a closure seal as claimed in claim 5 wherein the operating lever (14) is pivotally connected to the stabilizer (10).

7. The feeding structure as claimed in claim 4, wherein the inner wall of the end of the supporting portion (9) away from the conveyer belt (1) is provided with an anti-dropping protrusion (15), and when the connecting portion (12) abuts against the end of the stabilizing hole (11) away from the conveyer belt (1), the stabilizing portion (10) abuts against the anti-dropping protrusion (15).

8. A feed efficient structure for use in bottle cap sealing according to claim 1 characterized in that the thickness of the top of the guide plate (5) is smaller than the thickness of the bottom and the opening of the top of the guide space (6) is larger than the opening of the bottom.

9. The efficient feeding structure for bottle cap sealing according to claim 1, wherein two driving shafts (16) and two supporting bodies (17) located between the two driving shafts (16) are arranged between the two limiting plates (2), the driving shafts (16) are rotatably connected with the limiting plates (2), two ends of the conveying belt (1) are respectively sleeved on the two driving shafts (16), the lower surface of the conveying belt (1) located at the upper side is movably attached to the upper surface of the supporting bodies (17), one end of the supporting body (17) close to the driving shafts (16) is provided with a first circular arc-shaped matching groove (18), one end of the transition plate (3) close to the conveying belt (1) is provided with a second circular arc-shaped matching groove (19), the inner wall of the first matching groove (18) is connected with the outer wall of the driving shafts (16), the inner wall of the second matching groove (19) is connected with the conveying belt (19), and the inner wall of the first matching groove (18) is connected with the outer wall of the conveying belt (1) (1) Have a set spacing between them.

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